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《Limnologica》2021
Ciliated protozoans are important constituents of periphytic communities in aquatic habitats, including river-floodplain ecosystems. As the knowledge about the diversity and ecological importance of periphytic ciliates in floodplain habitats is still limited, the main objectives of this study were to analyse the temporal variations in the community structure and functional role and reveal the main environmental factors controlling community dynamics. The study was conducted in one of the Danube's largest conserved floodplains – Kopački Rit in Croatia. In situ research included two experimental series in a lake, the first from spring till winter and the second from summer till winter. Samples were collected biweekly using glass slides as artificial substrates for periphyton development. During the study, two hydrological (low-water and high-water) periods interchanged. High-water periods were characterized by greater water transparency and nutrient concentrations, while electrical conductivity, chlorophyll a concentration, total suspended solids and particulate organic matter in water were higher during low-water periods. Furthermore, hydrological changes greatly affected the periphytic ciliate communities and the highest abundances were registered during low water levels. We identified a total of 133 ciliate taxa, among which the peritrichs, sessile filter feeders, were the dominant representatives in the periphyton, with the highest densities registered in the absence of floods. During extremely high water levels, the composition of the ciliate community in periphyton changed, with mobile ciliates, predators and filter feeders, becoming dominant. This study indicates that the main food source for periphytic ciliates in a floodplain lake are bacteria and algae, confirming the important role of these microorganisms in the lake food web, by making the carbon fixed in bacteria and algae available for the organisms of higher trophic levels. Additionally, periphytic ciliates have a considerable effect on planktonic organisms in the lake, thus connecting benthic and pelagic food webs, especially during low-water periods. 相似文献
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文章使用4种分离培养基, 从10个广西涠洲岛柳珊瑚样本中分离可培养真菌, 通过菌落形态观察和内转录间隔区序列系统发育分析, 得到涠洲岛柳珊瑚共附生真菌多样性信息, 并采用96孔板法测定了真菌发酵液乙酸乙酯提取物的抑菌活性和抗生物被膜形成活性。试验结果表明, 从涠洲岛柳珊瑚样本中分离得到191株共附生真菌, 鉴定为26个种。这些真菌均属于子囊菌门, 分布于6个属: 曲霉属(Aspergillus)、青霉属(Penicillium)、链格孢属(Alternaria)、枝孢菌属(Cladosporium)、黑孢霉属(Nigrospora)和Parengyodontium属。曲霉属(Aspergillus)为优势种属, 占总菌株种类的69.23%; 次优属为枝孢菌属(Cladosporium)。抑菌活性筛选发现有11种真菌至少对一种指示菌有抑制活性, 占菌种总数的42.31%; 有7种真菌对表皮葡萄球菌生物被膜形成具有抑制活性, 半数有效浓度(EC50)范围为40.3~155μg·mL-1, 菌株Penicillium cinnamopurpureum GXIMD00518、Aspergillus carneus GXIMD00519具有抗耐甲氧西林金黄色葡萄球菌生物被膜形成活性, EC50分别为105.4μg·mL-1和117.4μg·mL-1。 相似文献
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凡纳滨对虾(Litopenaeus vannamei)池塘生物膜低碳养殖技术研究 总被引:3,自引:2,他引:1
采用水体中设置生物膜净水栅对比实验的方法, 在6口土池开展生物膜原位修复技术对土池半咸水养殖凡纳滨对虾的节能减排、养殖效益及机理的研究。结果表明, 在135d的养殖期间, 处理组水质的pH、TAN、NO2-N、无机氮和无机磷浓度分别显著低于对照组7.5%、78.8%、76.2%、53.2%和66.1% (P<0.05), DO浓度极显著高于对照组13.5% (P<0.01); 弧菌数极显著低于对照组66% (P<0.01), 细菌总数、硅藻相对密度、藻类生物多样性指数分别极显著高于对照组206%、173%、25.6% (P<0.01), 藻类密度、蓝藻相对密度分别显著低于对照组64.7%、70% (P<0.05); 生物膜上的细菌总数高达5.8×109CFU/g, 而弧菌数为零; 虾养殖成活率、虾起捕规格、虾产量分别极显著高于对照组62.5%、53.9%、150% (P<0.01), 饲料系数极显著低于对照组26.8% (P<0.01), 处理组每公顷池塘养虾增加利润约22.1万元。池塘生物膜低碳养殖技术具有成本低、节能减排、增产增收、操作简便与易推广等优点, 具有广阔的应用前景。 相似文献
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致病性副溶血弧菌生物膜形成特性研究 总被引:2,自引:0,他引:2
采用改良的微孔板法测定了12株弧菌的形成生物膜的效果,选择形成生物膜效果最好的副溶血弧菌ND-02,进一步研究了环境因子对其生物膜形成的影响。实验结果显示副溶血弧菌ND-02菌株在静置培养24~36 h后形成成熟的生物膜,在起始菌浓度为107~108CFU/mL形成生物膜的量最大;在30℃,NaCl浓度为3%~5%,pH偏弱碱性时的生物膜OD590值最大;C 2a+促进副溶血弧菌生物膜的形成,而M 2g+抑制生物膜的形成;副溶血弧菌在分别经大黄鱼表皮黏液、肠黏液和肝脏提取液包被的的基质上形成生物膜的作用明显,鳃黏液和脾脏提取液中次之,肌肉提取液包被后生物膜形成量最低。以上结果表明,副溶血弧菌ND-02菌株能形成稳定而明显的生物膜,而且生物膜的形成受温度、NaCl浓度、pH值等环境因子的影响。 相似文献
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研究开发了一种由水生植物、水生动物及微生物膜构建的组合型浮床生态系统.在野外条件下,考察了该浮床对富营养化湖泊水在静态条件下的净化效果.结果表明,20 d内TN、TP的去除率分别为83.7%和90.7%,透明度也有大幅提高.而且,组合型浮床系统对有机物尤其是难降解有机物的去除能力较强,在25 d内,对r-BHC、HE、DDE、DDD、DDT的去除率分别为25.2%、63.8%、42.1%、71.6%和27.6%,氯苯、阿特拉津的去除率达55.9%和72.1%.水生动物的代谢活动提高了有机物的生物可降解性和氮磷的植物可利用性.该新型浮床可用于水源地水质改善、污水净化生态工程、富营养水体的生态恢复等. 相似文献
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Desert Potholes: Ephemeral Aquatic Microsystems 总被引:1,自引:0,他引:1
Marjorie?A.?ChanEmail author Katrina?Moser Jim?M.?Davis Gordon?Southam Kebbi?Hughes Tim?Graham 《Aquatic Geochemistry》2005,11(3):279-302
An enigma of the Colorado Plateau high desert is the “pothole”, which ranges from shallow ephemeral puddles to deeply carved
pools. The existence of prokaryotic to eukaryotic organisms within these pools is largely controlled by the presence of collected
rainwater. Multivariate statistical analysis of physical and chemical limnologic data variables measured from potholes indicates
spatial and temporal variations, particularly in water depth, manganese, iron, nitrate and sulfate concentrations and salinity.
Variation in water depth and salinity are likely related to the amount of time since the last precipitation, whereas the other
variables may be related to redox potential. The spatial and temporal variations in water chemistry affect the distribution
of organisms, which must adapt to daily and seasonal extremes of fluctuating temperature (0–60 °C), pH changes of as much
as 5 units over 12 days, and desiccation. For example, many species become dormant when potholes dry, in order to endure intense
heat, UV radiation, desiccation and freezing, only to flourish again upon rehydration. But the pothole organisms also have
a profound impact on the potholes. Through photosynthesis and respiration, pothole organisms affect redox potential, and indirectly
alter the water chemistry. Laboratory examination of dried biofilm from the potholes revealed that within 2 weeks of hydration,
the surface of the desiccated, black biofilm became green from cyanobacterial growth, which supported significant growth in
heterotrophic bacterial populations. This complex biofilm is persumably responsible for dissolving the cement between the
sandstone grains, allowing the potholes to enlarge, and for sealing the potholes, enabling them to retain water longer than
the surrounding sandstone. Despite the remarkable ability of life in potholes to persist, desert potholes may be extremely
sensitive to anthropogenic effects. The unique limnology and ecology of Utah potholes holds great scientific value for understanding
water–rock–biological interactions with possible applications to life on other planetary bodies. 相似文献
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River biofilms are dominant riverine biota with diverse microorganisms. They have been found to contribute greatly to river self‐purification for removal of nutrients and organic matter. This study intended to investigate the ability of naturally occurring river biofilms with changing seasons for the removal of the organophosphorus pesticide diazinon. Natural river biofilms from spring showed higher ability to remove diazinon (99.9% removal) than those from winter (77%) with light exposure. In contrast to control sets without biofilms under irradiation, 27% of diazinon removal in spring and 22% in winter may result from microbial activity within biofilms. Removal of diazinon by river biofilms could be attributed mostly to degradation due to low sorption capacity of biofilms. Spring biofilms had higher dissipation rates (0.265 and 0.486 d?1 for biofilms with different growth periods) than winter ones (0.099 and 0.119 d?1) according to first order model. Higher ability of diazinon removal by spring biofilms may be explained by their higher bacterial and algal biomass comparing to winter biofilms. Naturally occurring river biofilms played a significant role in degradation of diazinon, particularly for those grown in spring. Their potential for use in the treatment of diazinon‐contaminated water has been demonstrated. 相似文献