光照和不同氮素对水葫芦谷氨酰胺合成酶活性的影响

谷氨酰胺合成酶(GS)是水葫芦氮代谢过程中一个关键酶,其活性受外界条件的影响。本研究探讨了光照和不同氮素对水葫芦根和叶GS活性的影响。研究发现,铵态氮和硝态氮抑制水葫芦根部GS活性,但却促进叶部GS活性。光照强度增加抑制根部GS活性,但对叶部GS活性影响不大。研究结果为揭示外来植物水葫芦快速入侵的机理,进一步开发和利用水葫芦进行水体修复提供理论基础。     

水葫芦三种铵转运蛋白基因片段的克隆及表达

目的:为了探讨水葫芦对富营养化水体中铵态氮吸收的分子机理。方法:采用简并引物克隆了3种水葫芦铵转运蛋白基因(EcAMT1、EcAMT2和EcAMT3)片段,并对这3个基因在不同形态的氮素条件下的表达进行了研究。结果:相比缺氮,铵态氮和硝态氮条件下,EcAMT1基因的表达被抑制,而EcAMT2和EcAMT3的表达刚好相反,铵态氮和硝态氮条件反而能够促进基因表达。结论:说明不同类型的铵转运蛋白基因的表达对外界环境因素的响应各不相同。     

太湖上游不同类型过境水氮素污染状况

利用GPS定位,在春、夏、秋、冬4个季节,对地处太湖上游宜兴地区受农田径流、农村生活污水、水产养殖和畜禽养殖污水污染的过境水体氮素污染状况进行了调查,对不同类型水体中不同形态氮浓度的季节性变化特征进行了分析,比较了不同类型水体的15N自然丰度.结果表明:不同类型过境水氮素污染严重,人为影响强烈,不同的农业生产和人类活动具有不同的污染特征;受农田径流影响的河流,水体受铵态氮污染的风险较小,受硝态氮的污染较重;农村居民区河流主要受农村生活污水影响,水体铵态氮负荷较高;畜禽养殖场附近的河流受养殖污水的影响,水体的氮素污染最为严重,尤其是铵态氮负荷最高;相比之下,养殖鱼塘水体总氮最低,主要以有机氮为主;水体氮素污染受河流季节性环境演变的影响,表现为夏季浓度最低,冬季浓度最高;农田施肥是太湖氮污染的主要来源,但在丰水期生活污水和畜禽养殖废水也会成为太湖重要的污染源.     

对水葫芦有杀草活性的菌株Ｓ63的分离筛选

采用水葫芦琼脂平板和氨氮平板初筛及点种于水葫芦茎处的方法,得到使水葫芦茎部病变黑斑的菌株,考察其对光照培养箱中培养水葫芦的生长抑制效果,获得对水葫芦生长有强抑制作用的菌株S63,鉴定为假单胞菌属。露天培养的试验结果表明,加入该菌液0.5%~2%(体积分数)的试验组发病率为41.2%~100%,高于对照组19.4%~33.3%的发病率;试验组叶片的丙二醛(MDA)含量、超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)的酶活均显著高于对照组。表明该菌对水葫芦有一定的除草活性。     

河岸带对陆地水体氮素输入的截流转化作用

氮素是陆地水体的重要污染物之一,相邻高地土壤中的氮素经非点源途径通过河岸带进入水体.河岸带是高地和水体之间的过渡带,健康的河岸带系统能够通过物理的、生物的和生物化学的过程,实现对氮素的截留转化.本文系统地介绍了氮素进入陆地水体的主要途径和河岸带对陆地水体氮素污染物截留转化的机制,并从河岸带水文过程、土壤特征、植被状况、人为活动等方面,论述了影响河岸带氮素截留转化作用的因素;在此基础上,对目前河岸带研究中存在的问题进行了讨论,并对我国开展河岸带的研究提出了建议.     

富营养化湖泊规模化种养的水葫芦与浮游藻类的相互影响

水葫芦(学名凤眼莲,Eichhornia crassipes Solms)是被公认为去除富营养化水体氮、磷效果较好的水生漂浮植物[1—3],也是目前生态修复工程中应用较广的水生漂浮植物[4]。随着《太湖流域控制性种养水葫芦技术规范》的出台,水葫芦安全控养模式在太湖流域的应用相对较为成熟。目前,研究者们对于水葫芦应用的顾虑由最初的影响     

水葫芦根际细菌群落结构多样性分析

【目的】了解水葫芦根际细菌群落结构。【方法】运用末端限制性片段长度多态性(Terminal restriction fragment length polymorphism,T-RFLP)技术分析富营养化水体中水葫芦根际和水葫芦近、远水样的细菌群落特征及多样性,结合克隆文库技术和培养法分析根际的细菌种群类型。【结果】同一时期水葫芦根际细菌多样性(Shannon-Weiner指数H′或Simpson指数D)更高,水葫芦近水样次之,远水样最小。10月份的细菌多样性高于5月份的。通过水葫芦根际细菌的克隆文库可知变形杆菌门(Proteobacteria)是水葫芦根际细菌的主要类群,占总群体的65.1%,包括噬菌弧菌(Bacteriovorax sp.)、Dechloromonas sp.、Leptothrix sp.、红螺菌科(Rhodospirillaceae)、Rhodoferax sp.和红环菌科(Rhodocyclaceae)等。T-RFLP图谱显示159 bp为最大优势菌,247 bp为第二大优势菌,对照克隆文库及培养结果分析247 bp属于γ-Proteobacteria,159 bp为不动杆菌(Acinetobacter sp.)。【结论】水葫芦根际细菌的群落结构丰富,不同时段水葫芦根际细菌的丰度略有变化,主要类群为变形杆菌门。     

水葫芦对藻类的克制效应

水葫芦对藻类生长有克制作用。其机制主要是由于水葫芦根系向水体分泌的有机物质能伤害和杀死藻类。用水葫芦种植水培养藻类,使藻类的光合作用速率显著降低,叶绿素a破坏,细胞还原TTC的能力下降。在荧光显微镜下可看到藻细胞从鲜红色变为淡蓝绿色。     

乡土水生植物对富营养化水体的净化效果研究

为了解乡土水生植物净化富营养化水体的效果,研究了广东地区5种乡土水生植物对2种富营养化水体总氮(TN)、总磷(TP)的净化效果和植物的生长状况。结果表明,与无植物空白相比,5种乡土植物使低、高浓度水体的TN去除率分别提高了3.8%～13.3%和13.2%～17.1%,TP去除率分别提高了15.2%～22.1%和11.3%～57.6%,其中野荸荠(Eleocharis plantagineiformis)适用于净化低氮水体;酸模叶蓼(Polygonumlapathifolium)适用于高氮水体;三白草(Saururuschinensis)适用于低磷水体;菱角(Trapa komarovii)适用于低氮或高磷水体;水龙(Ludwigia adscendens)对2种水体均有较好的净化效果,对高磷水体效果极佳。5种乡土植物在低、高浓度水体中均旺盛生长,水龙的生物量净增长率分别达375.5%和539.8%,表现最优,其次为菱角;水葫芦(Eichhorniacrassipes)则在高浓度水体中腐烂死亡,加重了水体污染。水龙、菱角对污染物的吸收作用较强,对P的吸收能力显著优于其他植物(P0.05)。因此,5种乡土植物均可作为广东地区富营养化水体修复的备选植物,其中水龙和菱角的开发潜力最大。     

水葫芦资源化综合利用的现状和建议

一、水葫芦的特性和危害状况 1．水葫芦的特性 水葫芦又名凤眼莲,原产南美,分类学上属雨久花科。中国是20世纪初当作动物饲料引进水葫芦的。水葫芦事实上有许多优良特性：营养丰富,能够富集水体中的N、P和多种重金属。专家指出,在适宜条件下,一公顷水葫芦能将800人排放的氮、磷元素当天吸收掉。24小时内每千克水葫芦能从污泥中除去铬0．67毫克、铅0．176毫克、汞0．150毫克、银0．65毫克、钴0．57毫克、锶0．54毫克。从某种角度分析,水葫芦还是治污能手。     

The role of eutrophication in the biological control of water hyacinth, <Emphasis Type="Italic">Eichhornia crassipes</Emphasis>, in South Africa

South Africa has some of the most eutrophic aquatic systems in the world, as a result of the adoption of an unnecessarily high 1 mg l⁻¹ phosphorus (P) standard for all water treatment works in the 1970 s. The floating aquatic macrophyte, water hyacinth (Eichhornia crassipes (Mart.) Solms (Pontederiaceae)), has taken advantage of these nutrient rich systems, becoming highly invasive and damaging. Despite the implementation of a biological control programme in South Africa, water hyacinth remains the worst aquatic weed. A meta-analysis of published and unpublished laboratory studies that investigated the combined effect of P and nitrogen (N) water nutrient concentration and control agent herbivory showed that water nutrient status was more important than herbivory in water hyacinth growth. Analysis of long-term field data collected monthly from 14 sites around South Africa between 2004 and 2005 supported these findings. Therefore the first step in any water hyacinth control programme should be to reduce the nutrient status of the water body.     

Ecological and socio‐economic impacts of invasive water hyacinth (Eichhornia crassipes): a review

1. Water hyacinth (Eichhornia crassipes) is one of the world’s most invasive aquatic plants and is known to cause significant ecological and socio‐economic effects. 2. Water hyacinth can alter water clarity and decrease phytoplankton production, dissolved oxygen, nitrogen, phosphorous, heavy metals and concentrations of other contaminants. 3. The effects of water hyacinth on ecological communities appear to be largely nonlinear. Abundance and diversity of aquatic invertebrates generally increase in response to increased habitat heterogeneity and structural complexity provided by water hyacinth but decrease due to decreased phytoplankton (food) availability. 4. Effects of water hyacinth on fish are largely dependent on original community composition and food‐web structure. A more diverse and abundant epiphytic invertebrate community may increase fish abundance and diversity, but a decrease in phytoplankton may decrease dissolved oxygen concentrations and planktivorous fish abundance, subsequently affecting higher trophic levels. 5. Little is known about the effects of water hyacinth on waterbird communities; however, increases in macroinvertebrate and fish abundance and diversity suggest a potentially positive interaction with waterbirds when water hyacinth is at moderate density. 6. The socio‐economic effects of water hyacinth are dependent on the extent of the invasion, the uses of the impacted waterbody, control methods and the response to control efforts. Ecosystem‐level research programmes that simultaneously monitor the effects of water hyacinth on multiple trophic‐levels are needed to further our understanding of invasive species.     

中国南部基塘区农业模式的变迁与凤眼蓝的入侵

为了探究凤眼蓝(别名凤眼莲, Eichhornia crassipes)入侵中国南部基塘区的主要原因, 对历史文献与档案资料进行了综合分析, 结果表明: 凤眼蓝在中国大陆的出现早于1930年。1911年后, 凤眼蓝曾入侵浙江省杭嘉湖平原水网河道。凤眼蓝也是1911年以来珠江三角洲地区十分常见的水生植物。1911-1980年, 基塘农业是浙江省的杭嘉湖地区和广东省珠江三角洲地区的典型农业经营模式, 凤眼蓝在这两个地区都曾被用作有机肥。20世纪50年代末至70年代, 长江流域曾推广凤眼蓝栽培技术, 对凤眼蓝进行了大规模的养植, 但1950-1980年的广积肥运动控制了凤眼蓝的繁殖速度和规模。1980年以来, 基塘地区成为长江三角洲和珠江三角洲城镇化与工业化快速发展的区域, 传统的循环农业经营模式普遍被废弃, 同时, 基塘区河网湿地水文生态环境的改变是凤眼蓝入侵中国南部基塘区的主要原因。     

Potential impacts of water hyacinth invasion and management on water quality and human health in Lake Tana watershed,Northwest Ethiopia

Incursion of water hyacinth, Eichhornia crassipes, has been a potential threat to Lake Tana and its ecosystem services. Its expansion is currently managed by abstraction (removing by hand); nonetheless, the disposal of mats and formation of pools are remaining problematic. This study aimed to assess the potential effects of water hyacinth and its management on water quality and human health. Biotic and abiotic data were collected on open water, water hyacinth covered and water hyacinth cleared out habitats. A total of 3673 invertebrates belonging to twenty-one families were collected from 45 sites. Culicidae was the most abundant family accounting (37.2%), followed by Unionoidae (19.4%) and Sphaeriidae (8.1%). Abundance of anopheline and culicine larvae were significantly higher in water hyacinth cleared out habitats (p?<?0.05). Water conductivity and total dissolved solids were significantly higher in habitats covered with water hyacinth (p?<?0.05). In conclusion, water hyacinth infestation had a negative impact on water quality and biotic communities. The physical abstraction of water hyacinth provided a very good habitat for the proliferation of mosquito larvae. Therefore, integrating water hyacinth management practices along with mosquito larvae control strategy could help to abate the potential risk of malaria outbreak in the region. In addition, developing watershed scale nutrient management systems could have a vital contribution for managing water hyacinth invasion in the study area.     

Impact of nutrients and herbivory by Eccritotarsus catarinensis on the biological control of water hyacinth,Eichhornia crassipes

Many water hyacinth infestations in South Africa are the symptom of eutrophication, and as a result, biological control of this weed is variable. This study examined the effects of herbivory by the mirid, Eccritotarsus catarinensis, on water hyacinth grown at high, medium and low nitrogen (N) and phosphorus (P) nutrient concentrations. Water nutrient concentration appears to be the overriding factor affecting plant growth parameters of water hyacinth plants—at high nutrient concentrations, leaf and daughter plant production were more than double than at low nutrient concentrations, while stem length was twice as great at high nutrient concentrations compared to low concentrations. Chlorophyll content was also twice as high at high nutrient concentrations than low concentrations. Conversely, flower production at high nutrient concentrations was less than half that at low concentrations. Herbivory by E. catarinensis did not have as great an effect on water hyacinth vigour as nutrient concentration did, although it significantly reduced the production of daughter plants by 23 ± 9%, the length of the second petiole by 13 ± 5%, and chlorophyll content of water hyacinth leaves by 15 ± 6%. In terms of insect numbers, mirids performed better on plants grown under medium nutrient conditions (99 ± 28 S.E.), compared to high nutrient concentrations (52 ± 27 S.E.), and low nutrient concentrations (25 ± 30 S.E.). Thus, these results suggest that the fastest and most significant reduction in water hyacinth proliferation would be reached by lowering the water nutrient concentrations, and herbivory by E. catarinensis alone is not sufficient to reduce all aspects of water hyacinth vigour, especially at very high nutrient concentrations.     

Effects of 2,4-D on mature and juvenile plants of water hyacinth (Eichornia crassipes (Mart.) Solms)

The effects of various concentrations of the herbicide 2,4-D were investigated on two vegetative forms of water hyacinth including juvenile and mature forms. The results obtained suggest that efficient chemical control of water hyacinth may be best applied at the early stages of vegetative development of the water hyacinth, i.e. at the juvenile phase. This would require the use of 2,4-D at a concentration of 60 000 ppm (2.2 kg/ ha) which equals to half the rate of 2,4-D normally used for control of water hyacinth in the Sudan. The lower rate of 2,4-D not only means a considerable reduction in quantity and cost of the consumed herbicide but also a substantial minimisation in the level at which pollution may build up in the White Nile of the Sudan.     

Experimental and kinetic modelling studies on the acid-catalysed hydrolysis of the water hyacinth plant to levulinic acid

A comprehensive experimental and modelling study on the acid-catalysed hydrolysis of the water hyacinth plant (Eichhornia crassipes) to optimise the yield of levulinic acid (LA) is reported (T=150-175 degrees C, [Formula: see text] , water hyacinth intake=1-5wt%). At high acid concentrations (>0.5M), LA was the major organic acid whereas at low acid concentrations (<0.1M) and high initial intakes of water hyacinth, the formation of propionic acid instead of LA was favoured. The highest yield of LA was 53mol% (35wt%) based on the amount of C6-sugars in the water hyacinth (T=175 degrees C, [Formula: see text] , water hyacinth intake=1wt%). The LA yield as a function of the process conditions was modelled using a kinetic model originally developed for the acid-catalysed hydrolysis of cellulose and good agreement between the experimental and modelled data was obtained.     

Seasonal variation in the nitrate content of water hyacinth (Eichhornia crassipes [Mart.] solms)

Water hyacinth was cultured in a flow-through system with constant nutrient availability and 1.4 mg 1^?1 NO₃-N as the nitrogen source. Tissue nitrate content ranged from 0.05 to 0.21% of dry wt. and accounted for 1.7–6.6% of the total nitrogen in the plant. Highest tissue nitrate levels occurred during the winter period of low plant growth rates and decreased as dry matter productivity increased. In the winter, the nitrate content of water hyacinth exceeded levels considered safe for conventional forage crops used for livestock feed.     

Eichhornia crassipes (Mart) solms: From water parasite to potential medicinal remedy

Water hyacinth, Eichhornia crassipes (Mart) Solms, originating in the amazonian basin, is a warm water aquatic plant. Water hyacinth is considered one of the most productive plants on earth and, accordingly, is considered one of the top ten world''s worst weeds. Water hyacinth spread to other tropical and subtropical regions by humans. It invaded about 62 countries in Africa, Asia and North America, and propagated extremely serious ecological, economical and social problems in the region between 40 degrees north and 45 degrees south. The dense weed of water hyacinth forms dense monocultures that can threaten local native species diversity and change the physical and chemical aquatic environment, thus altering ecosystem structure and function by disrupting food chains and nutrient cycling. We have separated and identified nine active fractions from water hyacinth and showed their promising therapeutic activities. Several compounds (alkaloid, phthalate derivatives, propanoid and phenyl derivatives) were identified in the extract of water hyacinth.Key words: water hyacinth, antimicrobial, anticancer, active compounds     

Sulphate uptake and metabolism in water hyacinth and salvinia during cadmium stress

Water hyacinth (Eichhornia crassipes (Mart.) Solms) and salvinia (Salvinia auriculata Aubl.) were exposed to toxic levels of Cd with the objective of evaluating its effect on sulphate uptake and metabolism. Plants were treated with 0 and 5 μmol L⁻¹ Cd for 3 days and, then sulphate uptake, ATP sulfurylase activity, soluble thiol content and Cd-binding complexes were determined. Water hyacinth showed a lower sulphate uptake, but its kinetic parameters were not affected by Cd. In salvinia, however, both V_max and affinity to sulphate (1/K_m) decreased with Cd treatment. The ATP sulfurylase activity increased in Cd-treated plant of both species, except in the roots of salvinia. In the presence of Cd water hyacinth always exhibited higher activity of this enzyme. The total soluble thiol content was always higher in water hyacinth. In Cd treated plants it increased in the leaves of water hyacinth, but decreased in salvinia. Cysteine content increased only in water hyacinth leaves, while γ-glutamylcysteine content increased in the two parts of the plants of both species after Cd treatment, especially in water hyacinth. Glutathione contents, on the contrary, after Cd treatment, reduced in both parts of the plants of water hyacinth but only in the leaves of salvinia. The unidentified thiol fraction content increased with Cd treatment in both species, especially in water hyacinth. Root and leaf extracts of both species showed peaks with maxima at A₂₆₅/A₂₈₀. In treated plants these peaks coincided with Cd content peaks indicating the formation of Cd-binding peptides. It was estimated that in the presence of Cd about 97% of Cd was associated with these complexes and water hyacinth had 28% more Cd-binding peptides than salvinia. Despite its lower sulphate uptake, water hyacinth showed higher rates of sulfur reduction and assimilation into soluble thiols. Possibly, glutathione is used in water hyacinth roots to synthesize hitherto unidentified Cd-binding peptides.