磺胺嘧啶对鱼菜共生系统氮元素转化的影响

本文研究了典型抗生素磺胺嘧啶对实验室规模鲤鱼-小白菜共生系统生产性能和氮元素转化的影响.结果表明,磺胺嘧啶使系统鲤鱼体重增量提高17%,但小白菜生产性能大幅下降,使得系统氮素利用率由43.66%降至21.20%,N₂O转化率由1.02%上升至1.98%.磺胺嘧啶在投加初期对系统的硝化过程表现出短期抑制效应,经过32d的适应期后,实验组氨氮浓度下降至和对照组相近水平,系统运行后期实验组氨氧化细菌丰度相较对照组提高51.43%.鱼体内残余的磺胺嘧啶为35.23μg/kg,符合国家标准,但水体中磺胺类药物抗性基因sul1、sul2及intI1的拷贝数分别提升至7.23倍、2.74倍和4.12倍.从生产性能及环境友好性考虑,鱼菜共生系统在设计及运行中应减少或避免抗生素的使用,并采取合理的替代措施规避其风险.     

稻田土壤氧化亚氮产生潜势、反硝化功能基因丰度和群落结构的垂向分布

土壤中氧化亚氮（N₂O）的释放量占全球N₂O释放总量的60%.其中，稻田土壤是N₂O最主要的释放源.反硝化过程是稻田土壤N₂O生成的主要微生物过程之一.本研究选取广东韶关稻田垂向土壤（0~100 cm）为研究对象，通过乙炔抑制剂法测定了N₂O产生潜势和反硝化潜势，并利用针对特异性功能基因的实时荧光定量和高通量测序技术分别分析反硝化功能基因丰度和反硝化微生物群落结构.结果显示：0~10 cm深度的土壤样品N₂O产生潜势最高，可达（0.020±0.0035）μg·g^-1·h^-1.反硝化功能基因中，nirK基因的丰度峰值（（1.51±0.0015）×10⁸ copies·g^-1）出现在0~10 cm深度，而nosZ和nirS基因的丰度峰值（（4.29±0.0015）×10⁷ copies·g^-1和（8.86±0.0010）×10⁷ copies·g^-1）均出现在10~20 cm深度.稻田垂向土壤中N₂O产生潜势和相关的反硝化功能基因（nosZ、nirK和nirS）丰度均随土壤深度的增加而逐渐降低.其中在所有深度的土壤样品中nirK基因的丰度均高于nirS.基于nirK基因的高通量测序结果发现慢生根瘤菌（Bradyrhizobium）的相对丰度最高（44.06%±6.14%，n=6）.相关性分析表明，稻田土壤中N₂O产生潜势与环境因子（TN、TC和含水率）、反硝化功能基因丰度以及慢生根瘤菌（Bradyrhizobium），罗河杆菌属（Rhodanobacter）和亚硝化螺菌属（Nitrosospira）的相对丰度呈正相关.上述结果表明稻田土壤中环境因子和反硝化功能基因丰度影响了N₂O产生潜势的垂向分布.     

Effects of bio-organic fertilizers on pineapple heart rot and bacterial community structure北大核心CSCD

Heart rot is a common soil-borne disease in the pineapple industry, but the situation can be alleviated by the application of bio-fertilizers with beneficial microbiomes. Clarifying the controlling mechanism of bio-organic fertilizer on the high incidence of heart rot is critical in monocultural pineapple cropping patterns. In our study, the soil of continuous cropping pineapple orchards was collected. Three types of carriers (rapeseed cake, peat soil, and coconut bran), biocontrol strains (Bacillus subtilis HL2 and Streptomyces strain HL3), and organic fertilizer (YJ) were composted into different bio-fertilizers (KC, KN, KY, LC, LN, and LY), which were used in pot experiments. The controlling effect of the bio-fertilizer was determined based on the response of pineapple heart rot and bacterial communities to different fertilizing methods. Our results revealed that the incidence of heart rot in bio-fertilizer KC was the lowest, which decreased by 20% and 13.3%, respectively, compared to HF (chemical fertilizer, 16-16-16) and YJ (organic fertilizer). The richness and diversity of soil bacterial communities in all biofertilized treatments (KC, KN, KY, LC, LN, and LY) were significantly higher than those in HF. However, the α-diversity indices of the bio-fertilizers (KC, KN, and KY) were higher than those of LC, LN, and LY, and the bacterial community composition was significantly different. The bacteria GP4, GP6, Bacillus, and Azohydromonas were enriched in KC, KN, and KY, while the relative abundance of Streptomyces increased significantly in LC, LN, and LY. Furthermore, Spearman correlation analysis showed that the relative abundance of these bacterial groups was significantly negatively correlated with the incidence of pineapple heart rot. In summary, the application of bio-organic fertilizers can decrease the incidence of pineapple heart rot by altering the soil bacterial community structure and stimulating beneficial soil microorganisms, which is important for reconstructing the ecological balance in continuous pineapple orchards. © 2022 Authors. All rights reserved.     

Quantity and activity of ammonia-oxidizing archaea and bacteria and their contribution to ammonia oxidation in farmland soil of Qinghai-Tibet Plateau北大核心CSCD

Ammonia oxidation, the first and rate-limiting step of nitrification, is mainly performed by ammonia-oxidizing archaea (AOA) and ammonia-oxidizing bacteria (AOB). However, the activities of AOA and AOB in soil and their relative contribution to ammonia oxidation are unclear, and whether there is a significant correlation between the quantity of AOA and AOB and the ammonia oxidation rate is also controversial. In this study, quantitative PCR combined with acetylene (C2H2) and 1-octyne inhibition methods were used to determine the quantity and activity of AOA and AOB in wheat, highland barley, and oilseed rape soils in Nyingchi, Lhatse, Sangzhuzi, and Sangri counties on the Qinghai-Tibet Plateau. The results showed that the quantity of AOB ((2.34 ± 0.84) ×105 - (2.65 ± 1.07) ×106 copies g-1 dry soil) was significantly higher than that of AOA ((0.20 ± 0.10) ×104 - (4.02 ± 0.39) ×104 copies g-1 dry soil) in all the soil samples. Soil pH was the key factor affecting the quantity of AOB, and the total phosphorus and ammonium nitrogen in soil were the key factors affecting the quantity of AOA. The rates of ammonia oxidation in the farmland soils of Lhatse (2.42 ± 0.73 mg kg-1 d-1) and Sangzhuzi (3.24 ± 1.15 mg kg-1 d-1) were significantly higher than those in the soils of Nyingchi (1.17 ± 0.43 mg kg-1 d-1) and Sangri counties (0.88 ± 0.57 mg kg-1 d-1). The rates of ammonia oxidation in the farmland soils of Lhatse and Sangzhuzi were dominated by AOB, while those in the farmland soils of Nyingchi and Sangri counties were dominated by AOA. For crops, the ammonia oxidation rates of wheat and oilseed rape soils in all four regions were significantly higher than those of highland barley soil, whereas the activity of AOA and AOB was not influenced by crops. The ratio of nitrogen to phosphorus was the key factor influencing AOA activity, whereas soil pH and total carbon were the main factors influencing AOB activity. Additionally, the quantities of AOA and AOB were not significantly correlated with the total ammonia oxidation rates and AOA and AOB activity. Overall, our study suggests that both AOA and AOB play important roles in ammonia oxidation in farmland soils of the Qinghai-Tibet Plateau. Moreover, it is unreliable to predict the activity of AOA and AOB and their relative contribution to ammonia oxidation directly based on their number of amoA genes, and the activity of AOA and AOB should be directly and accurately measured. These results are important for understanding ammonia nitrogen removal processes, slowing nitrate loss, and reducing the emission of the greenhouse gas nitrous oxide in the farmland ecosystem of the Qinghai-Tibet Plateau. © 2022 Science Press. All rights reserved.     

白银矿区土壤重金属及可培养细菌重金属耐受性研究

对白银矿区土壤重金属进行分析研究,分离、筛选和鉴定了受污染土壤中的可培养细菌,并考察其对土壤中重金属胁迫的耐受性。结果表明：白银矿区王岘镇尾渣堆和东大沟河沟土壤重金属污染Pb＞Zn＞Cu;从污染最严重的土壤中分离、筛选出砖红色微杆菌（Microbacterium testaceum）、特基拉芽孢杆菌（Bacillus tequilensis）和解单端孢菌素微杆菌（Microbacterium trichothecenolyticum）3种细菌,其中菌株M1（Microbacterium testaceum）对Pb、Zn、Cu、Cd的胁迫具有明显的耐受性。     

Hybrid zeolite-based ion-exchange and sulfur oxidizing denitrification for advanced slaughterhouse wastewater treatment

The discharge of slau ghterhouse wastewater（SWW） is incre asing and its wastewater has to be treated thoroughly to avoid the eutrophication.The hybrid zeolite-based ion-exchange and sulfur autotrophic denitrification（IX-AD） process was developed to advanced treat SWW after traditional secondary biological process.Compared with traditional sulfur oxidizing denitrification（SOD）,this study found that IX-AD column showed:（1） stronger ability to resist NO₃^-pollution load,（2） low...     

一株源于污泥浓缩池厌氧除磷菌的分离、鉴定及特性研究

采用浓缩池污泥为细菌分离的种泥,利用传统和现代微生物的分离、鉴定相结合手段,分离出一株源于污泥浓缩池的厌氧除磷功能菌(NA菌),从细菌形态、生理生化和16S rDNA三方面确定了所得细菌的分类地位,利用静态厌氧反应对其进行厌氧除磷特性初探. 结果表明:可将NA菌鉴定为蜡状芽孢杆菌(Bacillus cereus),该菌株同时具有反硝化和厌氧除磷产生磷化氢(PH₃)的双重功能. 随着培养时间的不断增加,NA菌总数,TP去除率和PH₃生成量分别由第7天的1.2×103 mL-1,7.66%和0.124 mg/L上升至第21天的1.7×104 mL-1,11.50%和0.465 mg/L,PH₃生成量与TP去除率,NA菌总数之间表现为同步一致的正相关关系,但由于未进行驯化,NA菌的厌氧除磷产生PH₃的能力较弱.      

固定化菌藻系统及对污水中氮磷营养盐的净化效果

利用海藻酸钙分别包埋固定小球藻、活性污泥及其两者混合物.研究固定态小球藻与悬浮态小球藻对污水中氮磷营养盐的处理效果,实验结果表明固定态藻对氮磷的去除效果明显优于悬浮态藻,其原因主要由于海藻酸钙凝胶对氮磷的吸附,系统pH值提高引起氨的气提及磷酸盐的沉淀作用.研究固定化藻、同定化活性污泥及共固定化菌藻分别对污水中氮磷营养盐的处理效果,在同等条件下,固定化菌藻对氮磷的去除效果优于固定化活性污泥和固定化藻类.这项研究显示菌藻共生在污水处理中具有较大的潜力.     

不同C/N值下亚硝酸盐氧化菌和异养菌混合体系的微生物多样性

采用PCR-RFLP技术研究了不同C/N比下亚硝酸盐氧化菌及异养菌混合体系的微牛物多样性,并探讨了微生物菌群结构与其功能(硝化件能)的关系.C/N=0时,混合体系主要由自养菌和寡营养菌(85.1%)组成,包括亚硝酸盐氧化菌(NOB)、拟杆菌门、α-变形菌纲、浮霉菌门和绿色非硫细菌中的一些菌株.C/N=0.44时,混合体系中的自养菌减少,异养菌(主要是γ-变形菌纲的成员)大量出现.C/N=8.82时,γ-变形菌纲的菌株尤其是反硝化菌Pseudomonas sp.占主导(93.8%),与此同时,随着C/N升高,该混合体系的硝化性能也由专一的亚硝酸盐氧化过程转变为同时硝化反硝化过程.微生物菌群结构的转变较好地解释了其硝化性能的改变.本研究揭示了微生物菌群结构与其功能的内在联系,同时表明PCR-RFLP技术与化学分析相结合是研究微生物菌群结构与功能的有力工具.图3表2参13