厌氧和好氧处理过程中四环素抗药基因的丰度

为了了解抗生素生产废水不同处理过程(厌氧生物处理和好氧生物处理)中抗药基因的行为,本文以两种四环素(土霉素、金霉素)生产废水处理系统为调查对象,采用PCR和实时定量PCR(qPCR)方法考察厌氧和好氧处理过程中常见的6种四环素抗药基因(tet(A), tet(C), tet(G), tet(Q), tet(W), tet(X))及2种转移因子(I型整合子intI1, 异常插入序列ISCR3)的丰度特征.结果表明,tet(C)在所有样品中均未检出,其它基因在所有样品中检出.四环素生产废水处理系统中,厌氧污泥中tet(A)、tet(G)、tet(X)的相对丰度(与16S rRNA基因的比值)范围为(1.25±0.16)×10^-4~(4.52±0.002)×10^-2,显著低于好氧污泥[(9.88±0.67)×10^-5~(2.70±0.29)×10^-1],而tet(Q)、tet(W)在厌氧污泥中的相对丰度为(1.66±0.03)×10^-2~(7.48±1.22)×10^-2,比好氧污泥中[(1.94±0.12)×10^-3~(2.85±0.16)×10^-2]高1个数量级;转移因子intI1和ISCR3在厌氧污泥中相对丰度范围为(1.48±0.01)×10^-3~(2.61±0.31)×10^-2,显著低于好氧污泥[(1.18±0.15)×10^-1~(8.99±0.75)×10^-1],表明厌氧处理过程中由这两种转移因子介导的水平转移潜力较小.研究表明,好氧处理促进了tet(A)、tet(G)、tet(X)的传播,但对tet(Q)和tet(W)有控制效果,而厌氧处理过程与之相反.抗药基因的分布与水平转移因子、抗药机制、群落结构有关.     

Microbial community and functional genes in the rhizosphere of alfalfa in crude oil-contaminated soil

A rhizobox system constructed with crude oil-contaminated soil was vegetated with alfalfa (Medicago sativa L.) to evaluate the rhizosphere effects on the soil microbial population and functional structure, and to explore the potential mechanisms by which plants enhance the removal of crude oil in soil. During the 80-day experiment, 31.6% of oil was removed from the adjacent rhizosphere (AR); this value was 27% and 53%higher than the percentage of oil removed from the far rhizosphere (FR) and from the non-rhizosphere (NR), respectively. The populations of heterotrophic bacteria and hydrocarbon-degrading bacteria were higher in the AR and FR than in the NR. However, the removal rate of crude oil was positively correlated with the proportion of hydrocarbon-degrading bacteria in the rhizosphere. In total, 796, 731, and 379 functional genes were detected by microarray in the AR, FR, and NR, respectively. Higher proportions of functional genes related to carbon degradation and organic remediation, were found in rhizosphere soil compared with NR soil, suggesting that the rhizosphere selectively increased the abundance of these specific functional genes. The increase in water-holding capacity and decrease in pH as well as salinity of the soil all followed the order of AR>FR>NR. Canonical component analysis showed that salinity was the most important environmental factor influencing the microbial functional structure in the rhizosphere and that salinity was negatively correlated with the abundance of carbon and organic degradation genes.     

北江河水中抗生素抗性基因污染初步研究（Preliminary Studies on the Pollution Levels of Antibiotic Resistance Genes in the Water of Beijiang River, South China）

环境中细菌的耐药性,尤其是对抗生素的耐药性已成为影响生态环境的重要因素.论文采用抗生素抗性平板法调查了北江河水中四环素、红霉素及磺胺类这3类抗生素耐药性细菌的存在,采用定性PCR及荧光定量PCR方法分别研究了该水域sul1和sul2这2种磺胺类抗生素抗性基因(ARGs)的存在和含量水平.结果表明,所采集北江水域的9个样品中有5个对四环素有耐药性,7个对红霉素有耐药性,8个对磺胺二甲嘧啶有耐药性;定性PCR实验并经基因测序结果证实,5个样品含有sul1,4个样品含有sul2.进一步的PCR定量分析结果显示,7个样品中均检出sul1和sul2磺胺抗性基因,它们与内对照基因16S-rRNA表达量比值分别在10-2.56~10-0.52及10-3.25~10-1.24范围内,该结果显著高于美国科罗拉多州北部河流的研究结果.此外,数据分析也发现,sul1和sul2磺胺抗性基因的含量水平与该区域水中磺胺含量分布具有一定的相关性,表明外源性抗生素对河流的污染是诱导抗性基因的重要因素.     

皮质醇影响青鳉鳃内钠钾ATP酶基因表达的研究

目前河流中存在较高浓度的天然和人造糖皮质激素(如皮质醇等)污染,其可能对鱼类的渗透压调节和海河洄游产生影响.鱼类鳃内钠钾ATP酶对调节渗透压平衡、适应海河洄游等起关键性作用,有研究表明鱼类鳃内钠钾ATP酶基因表达受皮质醇调控.为此,论文克隆了青鳉钠钾ATP酶α和钠钾ATP酶β基因的序列片段,建立了实时定量RT-PCR测定方法,研究了盐度的增加对其基因表达的影响,并重点探讨了皮质醇对鱼类适应盐度时鳃内钠钾ATP酶基因表达变化的影响.结果表明,适应15‰盐水的青鳉鳃内钠钾ATP酶α和钠钾ATP酶β基因表达显著升高;在转入淡水48h后,钠钾ATP酶α和钠钾ATP酶β基因表达基本恢复到正常水平,但是转入含有100ng·L-1皮质醇暴露水平的淡水中,48h后钠钾ATP酶α基因表达仍处于较高水平,表明100ng·L-1浓度的皮质醇能够显著诱导鳃内钠钾ATP酶α的基因表达,可能干扰渗透压调节,对一些洄游鱼类的溯河过程可能构成潜在影响.     

水产养殖环境中抗生素抗性基因（ARGs）的研究及进展(Research Advancement of Antibiotics Resistance Genes（ARGs）in Aquaculture Environment)

抗生素在现阶段的水产养殖中具有不可替代的作用,但长期滥用抗生素会诱导水生动物体内产生携带抗性基因(ARGs)的细菌株,尤其是多重耐药性菌株的产生将使得各种疾病的治疗更加棘手.抗性基因一旦被排泄到水产环境中不仅会对养殖区域和周围的环境造成潜在的基因污染,而且还会通过各种可移动遗传元件如质粒、转座子、整合子等的水平迁移作用进入其他致病菌和环境细菌中,对人类的健康安全构成潜在的威胁.论文对抗生素抗性基因在水产养殖业中的来源、污染现状、潜在的传播途径和相关的检测方法进行了综述,指出了开展水产养殖业中抗生素抗性基因污染研究的必要性,建议政府和有关部门尽快进行水产养殖业抗生素抗性基因的污染机理与控制对策研究.     

纳米材料对环境抗生素抗性基因污染扩散影响的研究进展

抗生素抗性基因(antibiotic resistance genes,ARGs)的环境扩散严重威胁了人类健康和生态安全。除抗生素滥用所产生的选择性压力以外,其他环境物质也能影响ARGs的传播。而纳米材料的广泛应用使其不可避免地在环境中扩散并进而影响ARGs的环境分布。因此,笔者综述了近年来纳米材料影响ARGs污染扩散的研究,并探讨了纳米材料对ARGs传播的影响机制,旨在深入理解ARGs的环境扩散行为,为ARGs环境控制及纳米材料非毒性环境效应的评估提供理论和技术支持。     

Influence of reclaimed water discharge on the dissemination and relationships of sulfonamide,sulfonamide resistance genes along the Chaobai River,Beijing

Reclaimed water threatens the ecological safety of the Chaobai River. SMX, TMP, and SDZ were the first three abundant antibiotics in the research area. SRGs and intI1 were widespread with high abundance after reclaimed water recharge. The SRGs values followed the sequence: Summer>autumn>spring>winter. Strong correlations were detected between SRGs and environmental factors. Reclaimed water represents an important source of antibiotics and antibiotic resistance genes, threatening the ecological safety of receiving environments, while alleviating water resource shortages. This study investigated the dissemination of sulfonamide (SAs), sulfonamide resistance genes (SRGs), and class one integrons (intI1) in the surface water of the recharging area of the Chaobai River. The three antibiotics sulfamethoxazole, trimethoprim, and sulfadiazine had the highest abundance. The highest absolute abundances were 2.91×10⁶, 6.94×10⁶, and 2.18×10⁴ copies/mL for sul1, sul2, and intI1 at the recharge point, respectively. SRGs and intI1 were widespread and had high abundance not only at the recharging point, but also in remote areas up to 8 km away. Seasonal variations of SRGs abundance followed the order of summer>autumn>spring>winter. Significant correlations were found between SRGs and intI1 (R² = 0.887 and 0.786, p<0.01), indicating the potential risk of SRGs dissemination. Strong correlations between the abundance of SRGs and environmental factors were also found, suggesting that appropriate environmental conditions favor the spread of SRGs. The obtained results indicate that recharging with reclaimed water causes dissemination and enrichment of SAs and SRGs in the receiving river. Further research is required for the risk assessment and scientific management of reclaimed water.     

Distribution and removal of antibiotic resistance genes during anaerobic sludge digestion with alkaline,thermal hydrolysis and ultrasonic pretreatments

Sludge digestion is critical to control the spread of ARGs from wastewater to soil. Fate of ARGs in three pretreatment-AD processes was investigated. UP was more efficient for ARGs removal than AP and THP in pretreatment-AD process. The total ARGs concentration showed significant correlation with 16S rRNA gene. The bacteria carrying ARGs could be mainly affiliated with Proteobacteria. Sewage sludge in the wastewater treatment plants contains considerable amount of antibiotic resistance genes (ARGs). A few studies have reported that anaerobic digestion (AD) could successfully remove some ARGs from sewage sludge, but information on the fate of ARGs in sludge pretreatment-AD process is still very limited. In this study, three sludge pretreatment methods, including alkaline, thermal hydrolysis and ultrasonic pretreatments, were compared to investigate the distribution and removal of ARGs in the sludge pretreatment-AD process. Results showed that the ARGs removal efficiency of AD itself was approximately 50.77%, and if these three sludge pretreatments were applied, the total ARGs removal efficiency of the whole pretreatment-AD process could be improved up to 52.50%–75.07%. The ultrasonic pretreatment was more efficient than alkaline and thermal hydrolysis pretreatments. Although thermal hydrolysis reduced ARGs obviously, the total ARGs rebounded considerably after inoculation and were only removed slightly in the subsequent AD process. Furthermore, it was found that the total ARGs concentration significantly correlated with the amount of 16S rRNA gene during the pretreatment and AD processes, and the bacteria carrying ARGs could be mainly affiliated with Proteobacteria.     

Impacts of advanced treatment processes on elimination of antibiotic resistance genes in a municipal wastewater treatment plant

The distributions of ARGs were monitored in a WWTP in Harbin during six months. CASS had the best removal efficacy of ARGs compared to other processes in the WWTP. UV disinfection could effectively control the HGT. AGAC significantly remove ARGs and organics due to its high absorption capacity. Combination of ozone and AGAC significantly improve removal of ARGs and organics. Antibiotic resistance genes (ARGs) pose a serious threat to public health. Wastewater treatment plants (WWTPs) are essential for controlling the release of ARGs into the environment. This study investigated ARG distribution at every step in the treatment process of a municipal WWTP located in Harbin for six consecutive months. Changes in ARG distribution involved in two advanced secondary effluent treatment processes, ozonation and granular activated carbon (GAC) adsorption, were analyzed. Biological treatment resulted in the highest ARG removal (0.76–1.94 log reduction), followed by ultraviolet (UV) disinfection (less than 0.5-log reduction). Primary treatment could not significantly remove ARGs. ARG removal efficiency increased with an increase in the ozone dose below 40 mg/L. However, amorphous GAC (AGAC) adsorption with a hydraulic retention time (HRT) of 1 h showed better removal of ARGs, total organic carbon (TOC), total nitrogen (TN), and total phosphorus (TP) than ozonation at a 60 mg/L dose. UV treatment could efficiently reduce the relative ARG abundance, despite presenting the lowest efficiency for the reduction of absolute ARG abundance compared with GAC and ozone treatments. The combination of ozone and AGAC can significantly improve the removal of ARGs, TOC, TN and TP. These results indicate that a treatment including biological processing, ozonation, and AGAC adsorption is a promising strategy for removing ARGs and refractory organic substances from sewage.     

好氧-厌氧两相堆肥过程中抗生素耐药基因的变化特征及影响因素研究

针对堆肥处理过程中抗生素耐药基因（antibiotic resistance genes,ARGs）去除效率不高、诱导潜在致病菌传播扩散等环境安全问题,采用好氧-厌氧两相堆肥处理猪粪、秸秆,探讨ARGs丰度及微生物群落的变化特征,并明确影响ARGs相对丰度变化的关键因子.结果表明:与单一好氧相比,好氧-厌氧两相堆肥能更有效地降低部分ARGs及潜在致病菌的相对丰度,其中ermB、tetK的相对丰度分别降低了39.68%、72.19%,假单胞菌属（Pseudomonas）、梭菌属（Clostridium_sensu_stricto_1）的相对丰度分别降低了96.09%、90.07%.主成分分析（Principal Component Analysis,PCA）及冗余分析（Redundancy analysis,RDA）得出,微生物群落和环境因子均显著影响ARGs相对丰度的变化（P < 0.05）,贡献率分别为82.0%、71.2%.其中,梭菌属（Clostridium_sense_stricto_1）、黄杆菌属（Flavobacterium）、尿素芽孢杆菌属（Ureibacillus）和海洋杆菌属（Oceanobacillus）是影响ARGs相对丰度变化的主要微生物菌属;温度、电导率、含水率和pH是影响ARGs相对丰度变化的关键环境因子,贡献率分别为22.0%、16.7%、16.2%和15.0%.研究显示:与好氧堆肥相比,好氧-厌氧两相堆肥能更有效地去除ARGs,并抑制潜在致病菌的繁殖扩散,从而减少环境风险;然而部分ARGs和潜在致病菌仍存在增殖现象,因此亟需进一步优化好氧-厌氧两相堆肥工艺.