环境中抗生素抗性基因的水平传播扩散

抗生素抗性基因作为一类新型环境污染物,其在不同环境介质中的传播扩散可能比抗生素本身的环境危害更大,其中,水平基因转移是抗生素抗性基因传播的重要方式,是造成抗性基因环境污染日益严重的原因之一.本文系统阐述了抗生素抗性基因在环境中发生水平转移的主要分子传播元件及其影响因素,这对于正确揭示抗性基因的分子传播机制具有重要意义.结合多重抗药性的传播扩散机制,探讨了行之有效的遏制抗生素抗性基因传播扩散的方法和途径,并针对目前的污染现状,对今后有关抗生素抗性基因水平转移的研究重点进行了展望.     

畜禽养殖废物中抗生素和重金属抗性基因的产生机制和控制方法研究进展

动物饲料中常混有抗生素和重金属,导致外排的动物粪便中携带有抗生素和重金属,引发细菌产生耐药性和重金属抗性,继而产生抗生素抗性基因和重金属抗性基因。抗生素和重金属抗性基因污染已成为威胁人类身体健康及破坏生态环境的重大问题。本文从细菌进化的角度,明确了细菌的抗生素和重金属长期进化试验对抗性机制研究的重要性;抗生素抗性基因与重金属抗性基因间存在复杂的协同选择抗性,两者间相互影响,共同决定着细菌环境行为;抗性基因的水平转移增加了细菌在环境中的可变性,可移动遗传元件在抗性基因水平转移中发挥着重要作用。在抗性基因污染控制方面,高级氧化技术具有很好的抗性基因去除效果,尤其是UV/TiO₂氧化技术,能使抗生素抗性基因丰度减少4.7～5.8 log,减少率大于99.99%。其他的控制策略,如抗生素替代品博落回提取物以及噬菌体与抗生素结合使用,对于抗性基因的控制也具有重要意义。     

水环境中抗性基因去除技术研究进展

抗生素的滥用导致了环境中抗性基因的产生,抗性基因一旦形成便难以控制和消除。目前,抗性基因在水环境中普遍检出,传播扩散迅速,污染形势严重,对生态系统和人体健康构成了巨大威胁。本文综述了国内外关于去除水环境中抗性基因的技术进展,重点讨论了消毒技术(含紫外消毒和加氯消毒)、高级氧化技术(包括Fenton氧化、光催化氧化和臭氧氧化)和人工湿地技术对水中抗性基因的去除效果,指出了各技术的应用优势和限制,分析了存在的问题与解决措施,为今后这一方向的深入研究和实践应用提供科学依据和参考。     

抗生素抗性基因在环境中的传播扩散及抗性研究方法

抗生素在医药、畜牧和水产养殖业的大量使用造成了环境中抗性耐药菌和抗性基因日益增加,抗生素抗性基因作为一种新型环境污染物引起人们的广泛关注.本文综述了近年来国内外有关抗生素抗性基因的研究进展,其在水、土壤、空气等环境介质中和动,植物体内的传播扩散,以及开展环境中抗生素抗性基因研究的必要性,重点介绍了有关抗生素抗性（包括抗性细菌和抗性基因）的研究方法,指出抗性基因研究中存在的问题,并对未来的相关研究进行了展望.     

污水处理厂中四环素和磺胺类抗生素抗性基因的分布、传播及去除

近年来,抗生素滥用造成的抗性基因(ARGs)污染问题引起了人们的关注.四环素及磺胺类抗生素由于价格低廉被广泛使用,大量残留的四环素和磺胺通过各种途径进入污水处理厂,并进一步导致ARGs的污染.为深入了解四环素和磺胺类ARGs的污染及治理现状,本研究对污水处理厂中四环素和磺胺类ARGs的分布情况及传播机制进行了综述,并重点讨论了不同污水处理工艺对ARGs的去除效果.在此基础上,从加大污水处理厂ARGs污染调查、改进污水处理工艺以及探讨ARGs传播机制等方面进行了展望.     

环境抗生素抗性基因研究进展

抗生素耐药性及其在全球范围内的传播已成为国际关注的热点。本文结合最新文献,综述了抗生素抗性基因在环境中的来源、传播、分布以及新型抗性基因的发现等方面的研究进展。环境中抗生素抗性基因的来源主要是环境中细菌的内在抗性基因及随人或动物粪便排到体外的抗性细菌。功能宏基因组学技术的应用极大地丰富了人们对抗生素抗性组学的认知,并已从环境中筛选到多种新型抗性基因。近年来,由于抗生素在医疗以及养殖业中的大量使用,增加了抗性基因在环境中的丰度和多样性,加速了抗性基因在环境中的传播,在多种环境介质(如养殖水域、污水处理厂、河流、沉积物和土壤等)均检测到多种高丰度的抗生素抗性基因。我们建议今后在以下方面开展深入研究:(1)抗性基因传播和扩散的机制;(2)新型抗性基因筛选和抗性机制;(3)抗生素和抗性基因环境风险评估体系等。     

畜禽粪便中抗生素抗性基因的分布特征及消减技术研究进展

随着集约化畜禽养殖业的不断发展,兽用抗生素的长期使用导致畜禽粪便抗生素抗性基因污染日益严重,对生态环境和人类健康造成严重危害。如何有效消减畜禽粪便中的抗生素抗性基因成为当前研究热点。本文系统总结了畜禽粪便中抗生素抗性基因的产生途径、分布和影响因素,并阐述了好氧堆肥、厌氧消化及其强化工艺消减畜禽粪便抗生素抗性基因的研究进展,根据现有工艺研究存在的问题展望了今后的重点研究方向,为畜禽粪便中抗生素抗性基因的消减提供理论基础和技术支撑。     

土壤生态系统中抗生素抗性基因与星球健康:进展与展望

土壤-植物系统是抗生素抗性基因(简称抗性基因)从环境向人类传播扩散的一个重要途径,是环境抗性基因人群暴露的主要来源.通过对土壤-植物系统中抗性基因的研究,可以明确抗性基因在土壤生物中的分布及其传递,分析抗性基因食物链传递的风险及其规律,从而为控制抗性基因污染提供理论依据,保障人类健康.同时,其对于维护星球健康也具有重要的价值.本文总结了土壤(包括土壤动物肠道)和植物微生物组中抗性组的重要研究进展,强调了抗性基因流在土壤-植物系统中的流动给土壤生态系统带来的环境风险,最后提出了通过管理土壤-植物系统中的抗性基因流以保障星球健康的方案,并对未来研究进行了展望.     

气溶胶中抗生素抗性基因研究进展

抗生素的不合理使用导致细菌耐药问题日趋严峻,给人类健康造成巨大威胁。学者们对抗生素抗性菌和抗生素抗性基因(antibiotic resistance genes, ARGs)在多种环境介质中的环境行为开展了大量研究。气溶胶作为ARGs的潜在储存库,是抗生素抗性基因在环境中的重要传播途径之一。目前缺乏对其来源、传播、人类接触和健康风险系统性的梳理。本文针对人类生活功能场所、养殖场、城市污水处理厂和医院等4类气溶胶研究的典型场所,重点综述了上述4类典型场所中气溶胶ARGs的来源、传播途径及对人体的暴露和对健康的危害,为气溶胶中ARGs的预防和控制提供参考。     

土壤环境中典型抗生素残留及其与微生物互作效应研究进展

抗生素大量不规范使用,其残留对环境和人类健康造成严重威胁。污水灌溉和生物有机肥的施用使土壤成为抗生素的主要归趋地之一,抗生素残留对土壤微生物产生不同程度的影响。首先综述了土壤抗生素污染现状,进一步论述了土壤抗生素残留对抗性基因诱导和微生物群落结构的影响,重点介绍了微生物方法在去除抗生素污染方面的重要作用,并指出了土壤抗生素污染研究中存在的问题,对今后主要研究方向进行展望。     

Soil plastispheres as hotspots of antibiotic resistance genes and potential pathogens

In the Anthropocene, increasing pervasive plastic pollution is creating a new environmental compartment, the plastisphere. How the plastisphere affects microbial communities and antibiotic resistance genes (ARGs) is an issue of global concern. Although this has been studied in aquatic ecosystems, our understanding of plastisphere microbiota in soil ecosystems remains poor. Here, we investigated plastisphere microbiota and ARGs of four types of microplastics (MPs) from diverse soil environments, and revealed effects of manure, temperature, and moisture on them. Our results showed that the MPs select for microbial communities in the plastisphere, and that these plastisphere communities are involved in diverse metabolic pathways, indicating that they could drive diverse ecological processes in the soil ecosystem. The relationship within plastisphere bacterial zero-radius operational taxonomic units (zOTUs) was predominantly positive, and neutral processes appeared to dominate community assembly. However, deterministic processes were more important in explaining the variance in ARGs in plastispheres. A range of potential pathogens and ARGs were detected in the plastisphere, which were enriched compared to the soil but varied across MPs and soil types. We further found that the addition of manure and elevation of soil temperature and moisture all enhance ARGs in plastispheres, and potential pathogens increase with soil moisture. These results suggested that plastispheres are habitats in which an increased potential pathogen abundance is spatially co-located with an increased abundance of ARGs under global change. Our findings provided new insights into the community ecology of the microbiome and antibiotic resistome of the soil plastisphere.Subject terms: Microbial ecology, Environmental sciences     

Removal of intl1 and associated antibiotics resistant genes in water,sewage sludge and livestock manure treatments

Antibiotics resistant genes (ARGs) are frequently detected in different media, such as wastewater, sewage sludge, and livestock manure. ARGs have been evidenced to have more and more threats to our environment because of their increase in species and total abundances causing more attention especially in horizontal gene transfer (HGT). The integron, an important form of mobile gene elements transfer ARGs through HGT, is demonstrated to have a high risk to human beings, and the class 1 integron (intl1), a predominant integron, is a marker of the process of horizontal gene transfer. Tetracycline, sulfonamides, macrolide, beta-lactam, trimethoprim, and quinolone plasmid-mediated resistance genes, which are frequently detected in various media and different treatment processes, have been reported to have significant correlations with intl1. Considering the risk of ARGs, especially those associated with intl1, the removal of intl1 and associated ARGs from water, sludge and livestock manure has attracted much more attention recently. Therefore, the mechanism and removal of intl1 and associated ARGs in water depth treatment, sludge and livestock manure digestion and composting process are reviewed in this paper. Besides, the limitation of the current study in this field is discussed, and the key points in the future investigation are provided.     

环境中胞内胞外抗性基因的分离检测、分布与传播

抗生素抗性基因(ARGs)传播对人类健康具有潜在的风险。胞内抗性基因(iARGs)和胞外抗性基因(eARGs)是抗生素抗性基因的两种存在形式,其在不同环境介质中的分布与传播过程具有截然不同的特征。本文首先基于ARGs赋存形态的差异,对染色体抗性基因、质粒抗性基因、噬菌体抗性基因等ARGs的胞内/胞外分类给予明确界定,并根据环境样品来源归纳了现有分离检测技术的应用场景,总结了iARGs和eARGs在养殖场、污水处理厂、河道、海洋、大气等环境中的分布特征,同时比较了其在传播方式和传播能力上的差异,以期为ARGs的分类阻控和健康风险评估提供理论参考。     

Metagenomic analysis reveals the prevalence and persistence of antibiotic- and heavy metal-resistance genes in wastewater treatment plant

The increased antibiotic resistance among microorganisms has resulted into growing interest for investigating the wastewater treatment plants (WWTPs) as they are reported to be the major source in the dissemination of antibiotic resistance genes (ARGs) and heavy metal resistance genes (HMRGs) in the environment. In this study, we investigated the prevalence and persistence of ARGs and HMRGs as well as bacterial diversity and mobile genetic elements (MGEs) in influent and effluent at the WWTP in Gwangju, South Korea, using high-throughput sequencing based metagenomic approach. A good number of broad-spectrum of resistance genes (both ARG and HMRG) were prevalent and likely persistent, although large portion of them were successfully removed at the wastewater treatment process. The relative abundance of ARGs and MGEs was higher in effluent as compared to that of influent. Our results suggest that the resistance genes with high abundance and bacteria harbouring ARGs and MGEs are likely to persist more through the treatment process. On analyzing the microbial community, the phylum Proteobacteria, especially potentially pathogenic species belonging to the genus Acinetobacter, dominated in WWTP. Overall, our study demonstrates that many ARGs and HMRGs may persist the treatment processes in WWTPs and their association to MGEs may contribute to the dissemination of resistance genes among microorganisms in the environment.     

环境中抗生素抗性基因与I型整合子的研究进展

抗生素抗性基因(Antibiotic resistance genes,ARGs)作为一种新型污染物在不同环境中广泛分布、来源复杂,对生态环境和人类健康造成了很大的潜在风险。同时,Ⅰ型整合子(Int Ⅰ)介导的ARGs水平转移是环境中微生物产生耐药性的重要途径,Ⅰ型整合子整合酶基因(intI1)与ARGs丰度在环境中表现出了较高的正相关性,Int Ⅰ可以作为标记物在一定程度上反映ARGs在环境中的迁移转化规律和人类活动影响程度。本文介绍ARGs与Int Ⅰ在环境中的来源与分布,总结Int Ⅰ介导的ARGs迁移转化机制以及相关研究方法,并展望未来的研究发展趋势。     

Bacteriophages as antibiotic resistance genes carriers in agro-food systems

Antibiotic resistance genes (ARGs) are a global health concern. Antibiotic resistance occurs naturally, but misuse of antibiotics in humans and animals is accelerating the process of antibiotic resistance emergency, which has been aggravated by exposure to molecules of antibiotics present in clinical and agricultural settings and the engagement of many countries in water reuse especially in Middle East and North Africa region. Bacteriophages have the potential to be significant actors in ARGs transmission through the transduction process. These viruses have been detected along with ARGs in non impacted habitats and in anthropogenic impacted environments like wastewater, reclaimed water and manure amended soil as well as minimally processed food and ready to eat vegetables. The ubiquity of bacteriophages and their persistence in the environment raises concern about their involvement in ARGs transmission among different biomes and the generation of pathogenic-resistant bacteria that pose a great threat to human health. The aim of this review is to give an overview of the potential role of bacteriophages in the dissemination and the transfer of ARGs to pathogens in food production and processing and the consequent contribution to antibiotic resistance transmission through faecal oral route carrying ARGs to our dishes.     

污水处理厂生物气溶胶抗生素抗性污染特征、来源及潜在风险

污水处理厂是抗生素抗性基因（antibiotic resistance genes,ARGs）和抗生素抗性细菌（antibiotic resistant bacteria,ARB）重要的源和汇,生物气溶胶是ARGs和ARB自污水处理厂向周边环境释放的关键载体。目前缺乏对污水处理厂生物气溶胶抗生素抗性污染特征、来源及潜在风险的系统性总结。本文从采样方法、检测方法、逸散特征、来源、潜在危害和风险评估等方面对污水处理厂抗生素抗性污染研究现状进行综述。惯性采样法和过滤法是常用的污水处理厂抗生素抗性生物气溶胶主要采集方法,而宏基因组测序、组装和分箱为其ARGs组成、可移动性和宿主提供了有效的检测方法,抗多药类、抗杆菌肽类、抗氨基糖苷类、抗四环素类、抗β-内酰胺类、抗磺胺类、抗大环内酯类和抗糖肽类等抗性基因在污水处理厂PM₁₀、PM_2.5和PM_1.0颗粒物中广泛检出。格栅间、生化反应池和污泥处理单元是污水处理厂PM₁₀、PM_2.5和PM_1.0负载ARGs和ARB的主要释放单元。污水处理厂不同粒径生物气溶胶中致病性ARB的存在增加了抗生素治疗的难度,而污水和污泥对ARGs和ARB的释放起到了重要的源的贡献。本文在研究内容、研究技术和控制策略等方面也提出了相关展望,以期为污水厂生物气溶胶抗生素抗性污染的监测和防护提供参考和借鉴。