The role of micro-organisms in the ecological connectivity of running waters

1. Riparian zones hold a central place in the hydrological cycle, owing to the prevalence of surface and groundwater interactions. In riparian transition zones, the quality of exfiltrating water is heavily influenced by microbial activities within the bed sediments. This paper reviews the role of micro-organisms in biogeochemical cycling in the riparian-hyporheic ecotone. 2. The production of organic substances, such as cellulose and lignin, by riparian vegetation is an important factor influencing the pathways of microbial processing in the riparian zone. For example, anaerobic sediment patches, created by entrainment of allochthonous organic matter, are focal sites of microbial denitrification. 3. The biophysical structure of the riparian zone largely influences in-stream microbial transformations through the retention of organic matter. Particulate and dissolved organic matter (POM and DOM) is retained effectively in the hyporheic zone, which drives biofilm development and associated microbial activity. 4. The structure of the riparian zone, the mechanisms of POM retention, the hydrological linkages to the stream and the intensity of key biogeochemical processes vary greatly along the river continuum and in relation to the geomorphic setting. However, the present state of knowledge of organic matter metabolism in the hyporheic zone suggests that lateral ecological connectivity is a basic attribute of lotic ecosystems. 5. Due to their efficiency in transforming POM into heterotrophic microbial biomass, attached biofilms form an abundant food resource for an array of predators and grazers in the interstitial environments of rivers and streams. The interstitial microbial loop, and the intensity of microbial production within the bed sediments, may be a primary driver of the celebrated high productivity and biodiversity of the riparian zone. 6. New molecular methods based on the analysis of the low molecular weight RNA (LMW RNA) allow unprecedented insights into the community structure of natural bacterial assemblages and also allow identification and study of specific strains hitherto largely unknown. 7. Research is needed on the development and evaluation of sampling methods for interstitial micro-organisms, on the characterization of biofilm structure, on the analysis of the biodegradable matter in the riparian-hyporheic ecotone, on the regulation mechanisms exerted on microbiota by interstitial predators and grazers, and on measures of microbial respiration and other key activities that influence biogeochemical cycles in running waters. 8. Past experiences from large-scale alterations of riparian zones by humans, such as the River Rhine in central Europe, undeniably demonstrate the detrimental consequences of disconnecting rivers from their riparian zones. A river management approach that uses the natural services of micro-organisms within intact riparian zones could substantially reduce the costs of clean, sustainable water supplies for humans.     

Analysis of denitrifying communities in streams from an urban and non-urban catchment

Urbanization leads to degradation in water quality and has a major effect on the biota of streams, but its effect on microbial communities is not as well understood. DNA-techniques that target functional genes are being used to examine microbial communities, but less frequently applied to freshwater aquatic systems. Our aim was to determine whether terminal restriction fragment length polymorphism and sequence analysis of polymerase chain reaction-amplified (PCR) nosZ gene sequences could be used to show if there were measurable differences in the denitrifying community in two urban streams in catchments with contrasting degrees of catchment urbanization. Community structure in the sediments and associated riparian zones were studied at the contrasting sites. We showed that the denitrifying community in the sediments and riparian soils of the two streams were significantly different. There were also significant differences between the sediment and riparian zone communities within each of the sites. Terminal restriction fragment length polymorphism analysis proved to be a valuable technique that could resolve patterns of the denitrifying community in streams of contrasting degrees of urbanization, but sequence analysis was required to confirm the identity of the amplified products.     

Characterizing seasonal changes in physicochemistry and bacterial community composition in hyporheic sediments

The hyporheic zone of stream ecosystems is a critical habitat for microbial communities. However, the factors influencing hyporheic bacterial communities along spatial and seasonal gradients remain poorly understood. We sought to characterize patterns in bacterial community composition among the sediments of a small stream in southern Ontario, Canada. We used sampling cores to collect monthly hyporheic water and sediment microbial communities in 2006 and 2007. We described bacterial communities terminal-restriction fragment length polymorphism (TRFLP) and tested for spatial and seasonal relationships with physicochemical parameters using multivariate statistics. Overall, the hyporheic zone appears to be a DOC, oxygen, and nitrogen sink. Microbial communities were distinct from those at the streambed surface and from soil collected in the adjacent watershed. In the sediments, microbial communities were distinct between the fall, spring, and summer seasons, and bacterial communities were more diverse at streambed surface and near-surface sites compared with deeper sites. Moreover, bacterial communities were similar between consecutive fall seasons despite shifting throughout the year, suggesting recurring community assemblages associated with season and location in the hyporheic zone. Using canonical correspondence analysis, seasonal patterns in microbial community composition and environmental parameters were correlated in the following way: temperature was related to summer communities; DOC (likely from biofilm and allochthonous inputs) influenced most fall communities; and nitrogen associated strongly with winter and spring communities. Our results also suggest that labile DOC entering the hyporheic zone occurred in concert with shifts in the bacterial community. Generally, seasonal patterns in hyporheic physicochemistry and microbial biodiversity remain largely unexplored. Therefore, we highlight the importance of seasonal and spatial resolution when assessing surface- and groundwater interactions in stream ecosystems.     

二道白河河岸带植物群落最小面积与物种丰富度

河岸带是森林小流域单元的重要组成部分之一。由于河水的影响和边缘效应等因素的综合作用,河岸带植物群落与远离河岸带的森林群落在组成,结构和分布格局等方面存在较大差异,其如落最小面积也不同。本文对长白山原始阔叶红松林河岸带植物群落最小面积和物种丰富度进行了探讨。结果表明,河岸带植物群落的最小面积均小于远离河岸带的森林群落的最小面积,在河岸带,阔叶红松林群落的60,80和90％植物在时的平均最小面积分别约为80,180和320m^2;而远离河岸带的森林内部,相应的平均最小面积分别为260,380和480m^2左右。河岸带植物群落的物种丰富度普遍高于森林群落。     

Dissolved organic carbon influences microbial community composition and diversity in managed aquifer recharge systems

This study explores microbial community structure in managed aquifer recharge (MAR) systems across both laboratory and field scales. Two field sites, the Taif River (Taif, Saudi Arabia) and South Platte River (Colorado), were selected as geographically distinct MAR systems. Samples derived from unsaturated riverbed, saturated-shallow-infiltration (depth, 1 to 2 cm), and intermediate-infiltration (depth, 10 to 50 cm) zones were collected. Complementary laboratory-scale sediment columns representing low (0.6 mg/liter) and moderate (5 mg/liter) dissolved organic carbon (DOC) concentrations were used to further query the influence of DOC and depth on microbial assemblages. Microbial density was positively correlated with the DOC concentration, while diversity was negatively correlated at both the laboratory and field scales. Microbial communities derived from analogous sampling zones in each river were not phylogenetically significantly different on phylum, class, genus, and species levels, as determined by 16S rRNA gene pyrosequencing, suggesting that geography and season exerted less sway than aqueous geochemical properties. When field-scale communities derived from the Taif and South Platte River sediments were grouped together, principal coordinate analysis revealed distinct clusters with regard to the three sample zones (unsaturated, shallow, and intermediate saturated) and, further, with respect to DOC concentration. An analogous trend as a function of depth and corresponding DOC loss was observed in column studies. Canonical correspondence analysis suggests that microbial classes Betaproteobacteria and Gammaproteobacteria are positively correlated with DOC concentration. Our combined analyses at both the laboratory and field scales suggest that DOC may exert a strong influence on microbial community composition and diversity in MAR saturated zones.     

河岸带土壤重金属元素的污染及危害评价

测定了金水河流域河岸带土壤部分重金属的全量和土壤水溶液的离子含量,运用污染指数和生态风险评价法对流域内土壤重金属进行评价.不同土地利用类型中,漫滩V、Cr含量最高(130.89、363.29 mg·kg-1),草地Ni、Pb、Ti、Mn、Zn、Cu含量最高(32.52、24.61、4378.09、1289.62、91.44、29.71 mg·kg-1).这主要是因为草地、漫滩能够有效吸附和沉积重金属,同时人类活动明显增加重金属生态危害.金水河流域河岸带土壤Cr、Pb、Zn均超过土壤环境质量标准(GB 15618-1995).与此同时,河漫滩白浆化棕壤和钙质粗骨土碳酸钙含量高,对Pb、Zn有较强的吸附和固定作用,能够有效吸附和沉积重金属;河漫滩人类干扰较重,造成其重金属含量较高.评价结果表明,流域河岸带内重金属环境污染达到中、重度污染,生态危害等级为轻微到中等级别.提高土壤腐殖质含量是减轻污染危害及增强土壤自净能力的重要措施.     

Spatial and resource factors influencing high microbial diversity in soil.

To begin defining the key determinants that drive microbial community structure in soil, we examined 29 soil samples from four geographically distinct locations taken from the surface, vadose zone, and saturated subsurface using a small-subunit rRNA-based cloning approach. While microbial communities in low-carbon, saturated, subsurface soils showed dominance, microbial communities in low-carbon surface soils showed remarkably uniform distributions, and all species were equally abundant. Two diversity indices, the reciprocal of Simpson's index (1/D) and the log series index, effectively distinguished between the dominant and uniform diversity patterns. For example, the uniform profiles characteristic of the surface communities had diversity index values that were 2 to 3 orders of magnitude greater than those for the high-dominance, saturated, subsurface communities. In a site richer in organic carbon, microbial communities consistently exhibited the uniform distribution pattern regardless of soil water content and depth. The uniform distribution implies that competition does not shape the structure of these microbial communities. Theoretical studies based on mathematical modeling suggested that spatial isolation could limit competition in surface soils, thereby supporting the high diversity and a uniform community structure. Carbon resource heterogeneity may explain the uniform diversity patterns observed in the high-carbon samples even in the saturated zone. Very high levels of chromium contamination (e.g., >20%) in the high-organic-matter soils did not greatly reduce the diversity. Understanding mechanisms that may control community structure, such as spatial isolation, has important implications for preservation of biodiversity, management of microbial communities for bioremediation, biocontrol of root diseases, and improved soil fertility.     

大理河沉积物微生物碳源利用特征及其影响因素

沉积物是河流生态系统中氮磷等物质循环的重要场所,而微生物是河流生态系统的重要组成部分,探究沉积物中微生物群落碳源利用特征和功能多样性对于河流生态环境保护具有重要意义。利用Biolog Eco微平板法、基于主成分分析、冗余分析阐明了大理河流域沉积物中微生物群落碳源利用强度和功能多样性变化特征及其影响因素。结果表明：（1）从流域上游到流域下游,沉积物中微生物碳源利用强度逐渐降低,与上游相比,支流、中游、下游沉积物中微生物碳源利用强度分别降低了13.4%、30.5%、30.7%。（2）沉积物中微生物群落功能多样性存在差异,沉积物中微生物群落功能多样性（Shannon-Wiener多样性指数）表现为上游 > 支流 > 中游 > 下游,常见物种优势度（Simpson多样性指数）则表现为下游 > 支流 > 中游 > 上游。（3）与微生物代谢活动相关性较高碳源为糖类,其次是氨基酸类,聚合物类、羧酸类、胺类、酚酸类与微生物代谢活动相关性较低。（4）沉积物中全氮、氨氮、硝氮、有机碳含量是影响微生物群落功能多样性和碳源利用特征差异的主要因素。流域沉积物中合适的碳、氮水平对维持河流水生态健康具有重要的意义。     

神农架山地河岸带中珍稀植物群落特征

以领春木(Euptelea pleiospermum)、连香树(Cercidiphyllum japonicum)为优势种的珍稀植物群落是神农架山地中海拔地段河岸带中的典型群落类型.在神农架地区4大水系(沿渡河、香溪河、南河和堵河)的河岸带中共调查了48个样地,采用植物群落学方法,分析了该区山地河岸带中珍稀植物群落特征.结果表明:(1)群落中植物种类丰富,科属组成比较分散.共记录到维管束植物749种,隶属144科412属,其中每科仅记录到1个属的有72个科,每属仅记录到1个种的有256个属.(2)在科水平上,热带、亚热带成分与温带成分所占比例几乎相同,在属水平上温带成分占主导.东亚分布成分、中国特有成分所占比例较高,共记录了6个东亚特有科、50个东亚特有属,2个中国特有科、27个中国特有属.(3)中小型草质单叶的落叶阔叶高位芽和地面芽植物是决定该珍稀植物群落外貌的主要成分.(4)群落垂直结构复杂,成层现象明显.第一乔木亚层树冠层分布不连续,第一、第二乔木亚层和灌木层从高到低郁闭度逐渐增大,草本层盖度各样地差别较大,层间植物丰富.该山地河岸带中丰富的珍稀、特有和/或孑遗植物表现出该群落的古老、孑遗性.虽然该区多数珍稀植物为温带性质,但该珍稀植物群落整体上在种类组成、区系分布、生活型谱、叶片性质等方面表现出亚热带亚高山垂直带谱上常绿落叶阔叶混交林的过渡性特征.自上而下逐渐密集的群落垂直结构为幼苗稍耐荫、成年趋于喜光的珍稀植物的不同发育阶段提供了利于其生长的光环境.特殊的地理位置、独特的地形地貌和良好的水热条件使亚热带山地河岸带成为珍稀植物(尤其是孑遗植物)就地保护中一个关键而特殊的区域.     

大兴安岭北部多年冻土区河岸森林湿地土壤性质和微生物呼吸活性特征

多年冻土区河岸森林湿地是水文、生态和生物化学过程的关键区域。本研究以河岸森林湿地及其与泥炭地的交错带土壤为对象,分析了腐殖质层和不同深度土壤理化性质、生态化学计量和微生物呼吸活性( 微生物生物量碳、基础呼吸、微生物熵和代谢熵)特征。结果表明: 与大兴安岭多年冻土区泥炭地和河岸森林湿地的交错带相比,河岸森林湿地土壤理化性质主要分异在20 cm土层以下,其总碳、总氮含量和碳磷比、氮磷比显著降低,生态化学计量特征的变化主要是由于氮含量变化引起的,说明河岸森林湿地土壤氮转移相对较快,存在氮限制;交错带湿地土壤中钠、镁、钾和钙含量主要在30 cm土层发生分异,而河岸森林湿地土壤中钠、镁、钾和钙含量主要在20 cm土层发生分异,其镁含量与土壤总碳、总氮和总磷含量显著相关,说明土壤镁含量是大兴安岭河岸森林湿地的重要营养元素;河岸森林湿地和交错带腐殖质层微生物呼吸活性高于其他层土壤,说明其易分解的碳组分含量高;河岸森林湿地和交错带土壤微生物呼吸活性与土壤理化性质、生态化学计量特征及营养元素的相关性存在差异,而河岸森林湿地土壤总氮含量与微生物呼吸活性显著相关,说明大兴安岭河岸带湿地土壤微生物活性受氮的限制。     

土地利用变化对挠力河流域可溶性有机碳输出的影响

采用野外采样、室内分析、GIS及统计分析相结合的方法,研究了挠力河流域河水可溶性有机碳（DOC）浓度的季节性动态,以及年均尺度上全流域、100 m河岸带土地利用变化对河水DOC输出的影响.结果表明： 基流状态下,河水DOC浓度在春季、夏季显著高于秋季;有湿地存在的子流域DOC浓度的季节性动态与无湿地存在的子流域存在显著差异,且有湿地存在的子流域中DOC浓度的季节性变异与整个流域的趋势一致;年均尺度上,DOC浓度与全流域湿地以及100 m河岸带范围内的水田面积百分比呈显著正相关,而与全流域尺度的林地百分比呈显著负相关（P<0.05）.表明湿地的存在是影响挠力河流域河水DOC季节性变异的重要因素;全流域的湿地以及100 m河岸带范围内的水田对其具有显著的促进作用,而林地对其有显著的减缓效应,流域过去几十年的土地利用变化改变了河水DOC的平衡状况.     

清潩河(许昌段)流域生物群落特征及其与环境因子的关系

以清潩河(许昌段)流域为研究对象,通过野外调查和室内测定,对水生植物、河岸带植物和大型底栖动物的群落特征、水体和表层沉积物的环境因子特征进行研究,分析清潩河流域内的生物多样性.结果表明: 流域内共有水生植物12种,河岸带植物66种,大型底栖动物10种.群落间环境因子变异较大,其中,水体的铵氮、总氮、总磷、表层沉积物的氧化还原电位、重金属镉、汞、锌的变异显著.典范对应分析表明: 水体理化性质如化学需氧量、温度、pH、溶解氧、总磷是影响水生植物的关键环境因子;水体氧化还原电位、pH和表层沉积物的镍、汞、有机质、铅、镉是影响河岸带植物分布的关键因子;表层沉积物的pH、温度、氧化还原电位、砷、铅、镍和水体温度是影响大型底栖动物的关键环境因子.清潩河(许昌段)流域水质污染严重,生物群落多样性低,沿河的污水处理及保护与恢复生物类群的工作迫在眉睫.     

Impact of hydrodynamics (ex- and infiltration) on the microbially controlled phosphorus mobility in running water sediments of a cultivated northeast German wetland

To gain insight into the impact of hydrodynamics (ex- and infiltration) on microbial activities, the microbial community structure, and the dynamics of phosphate and other chemical parameters in running water sediments of two transects in a German wetland have been studied. Flow directions and Darcy flow rates at canal bottom were determined using temperature profiles in the groundwater zone near and beneath the canal. Besides the chemical composition of pore water and sediment, a suite of enzyme activities and phosphorus fractions have been analyzed in the sediment. Hydrological analysis proved that at one transect infiltrating and stagnant conditions alter frequently, whereas at the other transect exfiltration dominates. We found significant differences between the transects in microbial activities and organic and iron-bound phosphorus as well as significant correlations between Darcy flux, microbial activities and phosphorus fractions. We conclude that not only the direction and rates of the flow, but also the quantity of changes between ex- and infiltration have an impact on microbial activity, and thus on phosphorus dynamics in the sediment of wetlands.     

丹江口水库水滨带植物群落空间分布及环境解释

探讨了环境因素对丹江口水库(南水北调中线水源地)水滨带植物群落空间分布的影响。通过对水滨带植物群落和环境因素的实地调查,用双向指示种分析(TWINSPAN)对201个水滨带植物群落进行分类;结合地形、土壤和水文因素用除趋势典范对应分析法(DCCA)分析环境因素对水滨带植物群落的影响;并对环境因素的解释能力进行定量分离。结果表明:(1)水滨带植物群落包括7种类型,分别是萹蓄群落、苘麻群落、细叶水芹+狗牙根群落、狗牙根群落、响叶杨-狗牙根群落、杜梨-白刺花-狗牙根群落和侧柏-牡荆-三穗苔草群落;(2)海拔和水淹影响对水滨带植物群落空间分布具有主导作用。海拔升高,水淹影响减弱,植物群落呈现由草本植物群落向木本植物群落变化的格局;(3)土壤因素的解释能力大于地形因素,水文因素的解释能力最小。各类环境因素之间存在交互作用,地形、水文和土壤因素三者间的交互作用最大,地形和土壤因素之间的交互作用最小。环境因素共解释水滨带植物群落空间分布的21.99%,未解释部分为78.01%。结果证明环境对植被的解释能力是由植被的复杂程度决定的,植被越复杂,环境的解释能力越低。     

漓江水陆交错带不同植被类型的土壤酶活性

水陆交错带是内陆水生生态系统与陆地生态系统之间的功能界面区,其包含了高地到低地直到水体的区域,是土壤有机质源、汇和转换器。土壤中有机物的分解以及营养物质的转化不仅影响到植物的生长,也对水体质量产生间接影响。土壤酶几乎参与土壤中有机物质的分解与合成的全过程,直接或间接影响着土壤一系列的生物化学反应,对生态系统的物质循环产生重要影响。不少学者围绕农田土壤、林地土壤以及湿地土壤探讨了不同植被下酶活性的变异。水陆交错带植被种类丰富,周期性的淹水条件加剧了土壤性质变异的复杂性。但目前水陆交错带不同植被类型土壤酶活性差异的研究不多。以漓江水陆交错带土壤为研究对象,对苔藓、草本和灌丛3种植被类型下的土壤溶解性化学成分、4种土壤水解酶即糖苷酶、几丁质酶、亮氨酸氨基肽酶和磷酸酶以及2种氧化还原酶即酚氧化酶和过氧化物酶的活性,以及土壤性质与酶活性之间的关系进行了研究。结果表明,苔藓植被下土壤的糖苷酶和酚氧化酶活性显著高于草本和灌丛,草本植被下土壤的过氧化物酶活性显著高于苔藓和灌丛,灌丛植被下土壤几丁质酶活性显著高于苔藓和草本,但不同植被类型的土壤亮氨酸氨基肽酶活性无显著差异。相关分析表明,土壤水分含量与糖苷酶和酚氧化酶活性呈显著正相关,而与几丁质酶和碱性磷酸酶活性呈显著负相关。土壤有机碳和易氧化碳均与糖苷酶和酚氧化酶活性呈极显著负相关,与几丁质酶活性呈显著正相关。土壤溶解性有机碳与亮氨酸氨基肽酶和酚氧化酶呈显著正相关。综合认为,水陆交错带不同种类土壤酶在不同植被类型间的差异有别,土壤水分含量和土壤有机碳显著影响土壤酶活性的变化。不同植被类型土壤酶活性的差异不仅与植被类型有关,与水陆交错带微地形以及土壤性质的空间异质性也有密切关系,需运用长期控制试验手段开展研究。     

Influence of electron acceptor availability and microbial community structure on sedimentary methane oxidation in a boreal estuary

Methane is produced microbially in vast quantities in sediments throughout the world’s oceans. However, anaerobic oxidation of methane (AOM) provides a near-quantitative sink for the produced methane and is primarily responsible for preventing methane emissions from the oceans to the atmosphere. AOM is a complex microbial process that involves several different microbial groups and metabolic pathways. The role of different electron acceptors in AOM has been studied for decades, yet large uncertainties remain, especially in terms of understanding the processes in natural settings. This study reports whole-core incubation methane oxidation rates along an estuarine gradient ranging from near fresh water to brackish conditions, and investigates the potential role of different electron acceptors in AOM. Microbial community structure involved in different methane processes is also studied in the same estuarine system using high throughput sequencing tools. Methane oxidation in the sediments was active in three distinct depth layers throughout the studied transect, with total oxidation rates increasing seawards. We find extensive evidence of non-sulphate AOM throughout the transect. The highest absolute AOM rates were observed below the sulphate-methane transition zone (SMTZ), strongly implicating the role of alternative electron acceptors (most likely iron and manganese oxides). However, oxidation rates were ultimately limited by methane availability. ANME-2a/b were the most abundant microbial phyla associated with AOM throughout the study sites, followed by ANME-2d in much lower abundances. Similarly to oxidation rates, highest abundances of microbial groups commonly associated with AOM were found well below the SMTZ, further reinforcing the importance of non-sulphate AOM in this system.

     

黄河干流河岸带植物群落特征及其影响因子分析

作为河岸带生态系统的关键组成部分,河岸带植被为许多动植物提供了栖息地以及迁徙或扩散的廊道,并对非点源污染物有着缓冲和过滤作用。黄河是我国湿地的重要组成部分,也是生物多样性分布的关键地带。但是,目前黄河水资源的过度利用如农业灌溉和干流拦河水利工程的兴建在很大程度上改变了原有的水文情势,对河岸带植被发育带来了不利影响。另外,黄河两岸的加固硬化进一步破坏了河岸带植物的生存环境。然而,过去对于黄河河岸带植被仅有对个别河段的调查。为了解目前黄河河岸带植被现状,于2008年4-6月及2008年9-10月对黄河干流河岸带植被进行了两次系统调查,以期为黄河河岸带植被多样性的保护、河岸带的开发管理提供理论支持。对群落的物种组成、多样性进行了分析,并采用双向指示种分析法对黄河干流河岸带植被进行了数量分类。共采集到木本和草本植物169种,隶属于37科124属。区系分析表明黄河干流河岸带植被区系地理成分多样。空间分布方面,中游河段草本植物无论在种类数、密度、生物量上都较上游和下游河段丰富。TWINSPAN将植被划分为17个群落,论述了各群落的特征。环境分析表明,影响黄河干流河岸带植被空间分布的主要生态因子是海拔、年均气温、年均降雨量、年均径流量和平均最大流速。       

Nutrient Vectors and Riparian Processing: A Review with Special Reference to African Semiarid Savanna Ecosystems

Abstract This review article describes vectors for nitrogen and phosphorus delivery to riparian zones in semiarid African savannas, the processing of nutrients in the riparian zone and the effect of disturbance on these processes. Semiarid savannas exhibit sharp seasonality, complex hillslope hydrology and high spatial heterogeneity, all of which ultimately impact nutrient fluxes between riparian, upland and aquatic environments. Our review shows that strong environmental drivers such as fire and herbivory enhance nitrogen, phosphorus and sediment transport to lower slope positions by shaping vegetative patterns. These vectors differ significantly from other arid and semiarid ecosystems, and from mesic ecosystems where the impact of fire and herbivory are less pronounced and less predictable. Also unique is the presence of sodic soils in certain hillslopes, which substantially alters hydrological flowpaths and may act as a trap where nitrogen is immobilized while sediment and phosphorus transport is enhanced. Nutrients and sediments are also deposited in the riparian zone during seasonal, intermittent floods while, during the dry season, subsurface movement of water from the stream into riparian soils and vegetation further enrich riparian zones with nutrients. As is found in mesic ecosystems, nutrients are immobilized in semiarid riparian corridors through microbial and plant uptake, whereas dissimilatory processes such as denitrification may be important where labile nitrogen and carbon are in adequate supply and physical conditions are suitable—such as in seeps, wallows created by animals, ephemeral wetlands and stream edges. Interaction between temporal hydrologic connectivity and spatial heterogeneity are disrupted by disturbances such as large floods and extended droughts, which may convert certain riparian patches from sinks to sources for nitrogen and phosphorus. In the face of increasing anthropogenic pressure, the scientific challenges are to provide a basic understanding of riparian biogeochemistry in semiarid African savannas to adequately address the temporal and spatial impact of disturbances, and to apply this knowledge to better regional land and water management. An integrated, multidisciplinary approach applied in protected as well as human-disturbed ecosystems in southern Africa is essential for underpinning a strong environmental basis for sustainable human-related expansion.     

Stream salinization is associated with reduced taxonomic,but not functional diversity in a riparian plant community

Abstract Dryland salinity presents an overwhelming threat to terrestrial and aquatic habitats in Australia, and yet there remains very little empirical evidence of the impacts of secondary salinization on the biodiversity of riparian communities. Here we describe the response of a riparian plant community to stream and soil salinization, 25 years after the experimental clearing of a catchment in south‐western Australia. Riparian plant species diversity was inversely related to soil salinity, and plant species composition was significantly altered by increased soil salinity. Despite the evidence for an impact of salinization on the taxonomic diversity and composition of the riparian plant community, there was little evidence for any effect of salinization on functional group diversity, or on ecological functioning, as measured by the percentage of above‐ground plant cover.