大气SO2、氟化物对植物生理生态指标的影响

运用多元回归分析方法研究不同污染区生长的植物叶片的生理生态指标的变化与大气硫酸盐化速率及氟化物浓度的关系.结果表明,植物的叶面积(LA)、叶绿素总量(Chl)、细胞液pH值(pH)和细胞质膜透性(CML电导率)等生理生态指标的变化幅度与大气污染物含量呈显著相关.与大气硫酸盐化速率关系式为Ys=0.034XLA-0.011XChl+0.017XpH+40.0003XCML+0.034(r=0.99,p＜0.001);与大气氟化物含量的关系式为YF=0.362XLA+0.329XChl+0.814XpH+0.024XCML-4.596(r=0.947,p＜0.03).利用这些生理生态指标的变化幅度作为生物监测的指标来评价不同污染区的大气硫氧化物、氟化物的污染状况,与大气监测结果有很高的一致性,并且与实际环境污染状况相符.     

佛山市几种绿地植物氟化物时空累积特征

对佛山市的防护绿地、公园绿地、生产绿地及附属绿地等城市绿地系统中的大叶榕、细叶榕、芒果、白兰、垂叶榕和尖叶杜英的叶片和各绿地系统中的大气氟化物含量进行了测定,并对其相互关系进行了研究。结果表明:四季中各绿地系统的大气氟化物含量均值的大小依次为防护绿地的工业区、交通区、附属绿地、生产绿地和公园绿地;工业区的大气氟化物浓度约为公园绿地的3.4倍,不同城市绿地系统的1、2年生植物叶片含氟量均随时间的延长而逐渐增加;大气氟化物与叶片含氟量之间存在密切相关性,反映了植物氟化物的空间累积特征,其中细叶榕和垂叶榕的1年生和2年生叶片、芒果的1年生叶片、白兰的2年生叶片中的氟化物浓度能较好地表征城市绿地系统中大气氟化物的浓度。     

植物叶绿素含量与大气中SO2浓度相关性研究

本文对厦门市5个样点、6种常见绿化树种及盆栽植物蕹菜的叶绿素含量、叶片含硫量及大气中SO_2浓度分析测定,得出了6种植物叶绿素a、b变化趋势是:鼓浪屿、厦门大学>火车站、后江埭>电化厂;叶片含硫量的变化趋势与叶绿素a、b含量变化相反。表明植物叶片叶绿素含量与大气中SO_2浓度和叶片含硫量呈负相关,并计算蕹菜叶绿素含量与大气SO_2浓度相关模式(y=-0.0138x 0.1958),为大气环境评价提供生物学依据。     

蚕豆叶片SOD活性监测大气SO2污染的可行性研究

 本文从实验室熏气和野外大气暴露两方面对利用蚕豆叶片SOD活性评价和监测大气SO2污染的可行性进行了研究。低浓度SO2(0.1312、0.2601mg·m-3)处理,引起叶片SOD活性升高,一定时间后,SOD活性趋于稳定,且0.2601mg·m-3SO2处理时,SOD活性较高,表现出SOD活性增量与SO2浓度相关,为利用SOD活性监测和评价SO2污染提供了可能性。大气暴露试验结果表明SOD活性与大气硫酸盐化速率存在极显著的相关性。利用SOD活性和大气硫酸盐化速率分别对大气SO2污染程度进行了评价,结果基本一致,并根据SOD活性估测了大气硫酸盐化速率,符合程度较高,置信分析表明估测结果可信。以上结果表明,利用蚕豆叶片SOD活性监测和评价大气SO2污染是可行的。     

Variations in the relationship between maximum leaf carboxylation rate and leaf nitrogen concentration

叶片最大羧化速率是表征植物光合能力的关键参数, 受到光照、温度、水分、CO₂浓度、叶片氮含量等多个要素的控制。准确地模拟植物叶片最大羧化速率对环境因子的响应是预测未来植被生产力和碳循环过程的前提。目前大多数陆地碳循环过程模型以Farqhuar光合作用模型为基础模拟植物的光合作用, 关于植物叶片的最大羧化速率与叶氮含量关系的模拟方法却各不相同。该文汇总了1990-2013年国内外植物叶片光合速率观测研究文献中叶片最大羧化速率与叶氮含量的关系式及相关数据, 分析了叶片最大羧化速率与叶氮含量关系随不同植被功能型和时间的变化特征, 以及环境因子变化条件下最大羧化速率与叶氮含量关系的变化特征, 探讨了二者关系变异性的可能原因以及影响因子。结果表明: 1)不同功能型植物叶片的最大羧化速率和叶氮含量的关系存在较大差异, 二者线性关系式的斜率平均值变化范围为16.29-50.25 μmol CO₂·g N^-1·s^-1。落叶植被叶片的最大羧化速率随叶氮含量的变化率和光合氮利用效率一般都高于常绿植被, 其变异主要源于植物的比叶重和叶片内部氮素分配的差异。2)叶片最大羧化速率随叶氮含量的变化存在季节和年际变异。在没有受到水分胁迫的年份中, 叶片最大羧化速率随叶氮含量变化的速率一般在春季或夏季最高, 其季节变异与比叶重和叶氮在Rubisco的分配比例的季节变化有关。受到干旱的影响, 叶片最大羧化速率随叶氮含量的变化率会升高。3)当大气CO₂浓度增加时, 由于叶片中Rubisco含量的降低, 多年生针叶叶片最大羧化速率和叶氮关系斜率值会出现降低; 当供氮水平增加时, 叶片最大羧化速率和叶片氮含量均表现出增加趋势, 二者线性关系的斜率也相应增加。在此基础上, 该文指出在模拟叶片最大羧化速率与叶氮含量的关系时, 应考虑叶片比叶重和叶氮在Rubisco中的分配比例的季节变异、水分胁迫、大气CO₂浓度和供氮水平变化对二者关系的影响。囿于数据的有限性, 今后应进一步加强多因子控制实验研究, 深入探讨叶片最大羧化速率与叶氮含量关系的变异性机理, 并获得更系统的观测数据, 以助生态系统过程模型的改进, 提高模型的模拟精度。     

植物叶片最大羧化速率与叶氮含量关系的变异性

叶片最大羧化速率是表征植物光合能力的关键参数, 受到光照、温度、水分、CO₂浓度、叶片氮含量等多个要素的控制。准确地模拟植物叶片最大羧化速率对环境因子的响应是预测未来植被生产力和碳循环过程的前提。目前大多数陆地碳循环过程模型以Farqhuar光合作用模型为基础模拟植物的光合作用, 关于植物叶片的最大羧化速率与叶氮含量关系的模拟方法却各不相同。该文汇总了1990-2013年国内外植物叶片光合速率观测研究文献中叶片最大羧化速率与叶氮含量的关系式及相关数据, 分析了叶片最大羧化速率与叶氮含量关系随不同植被功能型和时间的变化特征, 以及环境因子变化条件下最大羧化速率与叶氮含量关系的变化特征, 探讨了二者关系变异性的可能原因以及影响因子。结果表明: 1)不同功能型植物叶片的最大羧化速率和叶氮含量的关系存在较大差异, 二者线性关系式的斜率平均值变化范围为16.29-50.25 μmol CO₂·g N^-1·s^-1。落叶植被叶片的最大羧化速率随叶氮含量的变化率和光合氮利用效率一般都高于常绿植被, 其变异主要源于植物的比叶重和叶片内部氮素分配的差异。2)叶片最大羧化速率随叶氮含量的变化存在季节和年际变异。在没有受到水分胁迫的年份中, 叶片最大羧化速率随叶氮含量变化的速率一般在春季或夏季最高, 其季节变异与比叶重和叶氮在Rubisco的分配比例的季节变化有关。受到干旱的影响, 叶片最大羧化速率随叶氮含量的变化率会升高。3)当大气CO₂浓度增加时, 由于叶片中Rubisco含量的降低, 多年生针叶叶片最大羧化速率和叶氮关系斜率值会出现降低; 当供氮水平增加时, 叶片最大羧化速率和叶片氮含量均表现出增加趋势, 二者线性关系的斜率也相应增加。在此基础上, 该文指出在模拟叶片最大羧化速率与叶氮含量的关系时, 应考虑叶片比叶重和叶氮在Rubisco中的分配比例的季节变异、水分胁迫、大气CO₂浓度和供氮水平变化对二者关系的影响。囿于数据的有限性, 今后应进一步加强多因子控制实验研究, 深入探讨叶片最大羧化速率与叶氮含量关系的变异性机理, 并获得更系统的观测数据, 以助生态系统过程模型的改进, 提高模型的模拟精度。     

大气中几种污染物的植物监测

当大气受到污染后，植物就会不同程度地作出反应，如叶片的变色、脱落或枯死等。因此，可以利用植物对大气污染的异常反应，监测大气中有害物质的成分和含量，以了解大气的质量状况。大气污染中的主要有害物质有：臭氧、过氧酰基硝酸酯类、二氧化硫和氟化物等。 臭氧 这是一种气态的次生大气污染物，氮氧化物在阳光照射下发生复杂反应的产物。它具有很强的毒性。 当植物与其周围环境进行正常的气体交换时，臭氧经气孔进入植物叶片，诱发一系列的污染伤害。其急性典型症状为：叶片上均匀地散布着形状、大小较规则的细密点状斑，呈棕色或黄褐…     

夏秋季丹霞梧桐叶片光合特性日变化特征比较

利用便携式光合蒸腾仪于夏季、秋季各测定了国家重点保护植物丹霞梧桐(Firmiana danxiaensis Huse et H.S.Kiu)叶片的光合特性及生态因子,以期为了解该植物的生态适应性提供基础数据。结果表明:夏季测定日的气温、大气相对湿度、CO_2浓度、光合有效辐射、叶片SPAD值、净光合速率、蒸腾速率及气孔导度等光合特性等指标均高于秋季测定日的相应值,但叶片水分利用效率、各因子之间的相关性则夏季低于秋季。夏季在测定日平均气温近37.37℃高温下,大气相对湿度65.66%,丹霞梧桐叶片净光合速率平均为14.35μmol CO_2/m~2·s,蒸腾速率4.28 mmol H_2O/m~2·s,气孔导度184.33 mol H_2O/m~2·s;秋季测定日气温平均33.78℃,大气相对湿度41.97%,叶片净光合速率8.70μmol CO_2/m~2·s,蒸腾速率2.75 mmol H_2O/m~2·s,气孔导度85.19 mol H_2O/m~2·s;可见,丹霞梧桐在夏季以高的净光合速率、蒸腾速率和气孔导度,表现出对丹霞地貌高温高湿环境的高度适应性。     

基于光谱指数的植物叶片叶绿素含量的估算模型

叶绿素是光合作用能力和植被发育阶段的指示器,是监测湿地植被生长健康状况的重要指标之一;高光谱遥感技术可以为植物叶绿素含量的定量化诊断提供简便有效、非破坏性的数据采集和处理方法。为保证被探测叶片面积相同,消除背景反射、叶片表面弯曲造成的光谱波动及叶片内部变异造成的影响,研究采用Field Spec 3光谱仪加载手持叶夹式叶片光谱探测器,测定野鸭湖湿地典型植物的叶片高光谱反射率数据,同时通过分光光度计室内测定相应叶片的叶绿素含量。采用相关性及单变量线性拟合分析技术,建立二者的关系模型,包括叶绿素含量与"三边"参数的相关模型以及比值光谱指数(SR)模型和归一化差值光谱指数(ND)模型,并采用交叉检验中的3K-CV方法对估算模型进行模型精度检验。结果表明:植物叶片叶绿素含量与"三边"参数大多都呈极显著相关,相关系数最大达到0.867;计算光谱反射率组成的比值(SR)和归一化(ND)光谱指数与叶绿素含量的决定系数,总体相关性比较高,较好的波段组合均为550—700nm与700—1400nm以及550—700nm与1600—1900nm,与叶绿素含量相关性最好的指数分别是SR(565nm,740nm)和ND(565nm,735nm)。并通过选取相关性最佳的光谱特征参数,分别基于"三边"参数和ND模型指数构建了植物叶片叶绿素含量的估算模型。其中,基于红边位置(WP_r)光谱特征参数和ND(565nm,735nm)光谱指数建立的叶绿素含量估算模型,取得了较好的测试效果,检验拟合方程的决定系数(R2)都达到0.8以上,估算模型分别为y=0.113x-78.74,y=5.5762x+4.4828。通过3K-CV方法进行测试和检验,植物叶绿素含量估算模型均取得了较为理想的预测精度,预测精度的分别为93.9%及90.7%。高光谱遥感技术对植被进行微弱光谱差异的定量分析,在植被遥感研究与应用中表现出强大优势,为植物叶绿素含量诊断中的实际应用提供了重要的理论依据和技术支持。     

不同季节杉木幼苗叶片养分和代谢组分对增温和减少降水的响应

研究冬季和夏季亚热带杉木幼苗在增温5 ℃和减少50%自然降水处理下叶片养分和代谢组分的变化.结果表明: 由于不同季节温度和水分差异,杉木叶片的养分和生理代谢组分在不同季节有不同的表现.冬季杉木叶片碳、氮、磷和钾含量显著高于夏季.夏季减少降水、增温处理对杉木叶片各类抗氧化酶活性均无显著影响,冬季减少降水处理分别显著降低超氧化物歧化酶活性20.7%和过氧化物酶活性17.8%.冬季增温后杉木叶片非酶促的抗坏血酸含量显著增加132.5%.冬季增温+减少降水处理降低杉木碳含量,促进渗透物质脯氨酸和氮含量的累积.夏季增温+减少降水处理显著提高杉木叶片碳含量3.3%.无论是冬季还是夏季,增温+减少降水处理对杉木叶片抗氧化系统无显著影响.植物对夏季增温的适应机制与冬季增温不同,杉木叶片的养分变化对同时增温+减少降水更加敏感.为了更好地管理种植林,以提高植物的生产力,在未来气候变化下,应提高植物对养分供需和对季节响应的关注.     

Temporal variability of stream bioassessments using benthic macroinvertebrates

1. When using benthic macroinvertebrate communities for bioassessment, temporal variation may influence judgement as to whether or not a site is degraded.
2. In a survey of sixteen reference and sixteen test sites in the upper Thames River catchment area (UTRCA) in south-western Ontario, Canada, consistent differences between summer and winter samples were found for taxon richness (increase; P = 0.06) and the Family Biotic Index (decrease; P = 0.11). A bioassessment based on these results would indicate better water quality in the same streams in winter relative to summer. No consistent pattern of seasonal difference was detected for Simpson's Diversity and Equitability, or percentage Dominant Taxon.
3. The Reference Condition Approach to bioassessment uses predictive modelling to explain variation in reference communities with the environmental conditions at these sites as predictors. The community at a test site is compared with that predicted by the model. Several predictive models were constructed using simple geographic and habitat characteristics (i.e. catchment area, distance to source, stream width, substrate and habitat diversity) as predictors. By including season of sampling in the models, we increased their predictive power and the ability of the bioassessment to detect degradation. The best results were achieved when separate predictive models were built for each sampling season.     

校园空气污染微生物的检测与评价

采用沉降平板法 ,选用牛肉膏培养基与察贝克培养基 (czpekmedium) ,分别在夏季与冬季检测了校园不同环境中空气污染细菌与霉菌的含量。结果表明 :校园不同环境的空气污染微生物类群与数量随季节的变化而变化。学生寝室、学生食堂、校区餐厅以及网吧的空气中污染微生物以细菌为主。其中 ,在冬季的细菌平均含菌量为 91 4 7.6 7个 /m3 空气 ,而以女生寝室的含菌量最高 ,达到 2 1 5 4 6个 /m3 空气 ,超出卫生标准的 3.1倍 ;在夏季时 ,细菌的平均含菌量为 1 0 6 6 1 .75个 /m3 空气 ,而以校园餐厅的含菌量最高 ,达到 4 35 1 1个 /m3 ,超出卫生标准的 6 .9倍。校图书馆、电影院、学生寝室及餐厅中的霉菌含量较多。其中 ,在冬季的霉菌平均含菌量为 5 6 8.4 4个 /m3 空气 ,以女生寝室的含菌量最高 ,84 6个 /m3 ;在夏季的霉菌含菌量为 85 5 .88个 /m3 ,最高时为 1 6 6 5个 /m3 ,这是由于卫生条件差 ,居室狭小 ,人口拥挤 ,空气潮湿 ,通风不良等因素造成的     

Disparate determinants of summer and winter diet selection of a generalist herbivore,Ochotona princeps

The North American pika, Ochotona princeps, is a generalist herbivore that simultaneously selects two distinct diets: one consumed immediately (summer diet), the other harvested, transported, and stored for later consumption (winter diet). I investigated factors influencing diet selection at two sites on the West Knoll of Niwot Ridge, Boulder County, Colorado during 1991 and 1992. The composition of summer and winter diets differed significantly from each other as well as from the relative abundance of food items in the environment. Thus, pikas were not foraging randomly for either diet. To explore winter and summer diet selection, I tested two existing hypotheses: (1) that plant morphology restricts the winter diet breadth to plants that are easily harvested and large, and thereby maximizes the amount collected per foraging effort, or (2) to compensate for nutrients lost during storage, pikas bias their winter diet with high-nutrient species. I also tested the hypothesis that plant secondary compounds may be higher in the winter diet either because they function as preservatives or because pikas delay consumption of these species until the toxins degrade. For individual dietary items, I measured energy, nitrogen, water, fiber, total phenolic, condensed tannin, and astringency contents. There was little evidence to suggest that morphology excluded plants from the winter diet. Plant size was not a good predictor of abundance in the winter diet. Even after harvesting costs had been experimentally removed, cushion plants were still not included in the winter diet. There was weak support for an effect of nutrients on winter diet selection; in three of four cases, the winter diet was significantly lower in water and higher in total energy content as predicted by the nutrient compensation hypothesis. However, other nutrients exhibited no consistent pattern. Nutrients were not reliable predictors of the winter diet in multiple regression analyses. There was strong support for the hypothesis of manipulation of secondary compounds. The winter diet was significantly higher in total phenolics and astringency. Total phenolics were consistent predictors of the winter diet in multiple regression analyses. The winter diets of six additional pika populations contained plant species high in secondary compounds. The results suggest that pikas preferentially select plants with high levels of secondary compounds for their winter diet, possibly because the presence of such compounds promotes preservation of the cache. This behavior may also enable the exploitation of an otherwise unusable food resource, i.e., toxic plants.     

Temporal variation in the genotoxic potential of urban air particulate matter

The main aim of this study was to compare the genotoxic potential of organic extracts from urban air particles collected in three different sampling periods in the center of Prague (Czech Republic). For this purpose, we analyzed the DNA adduct forming activity of extractable organic matter (EOM) from urban air particles <10 microm (PM10) in the human hepatoma cell line HepG2. DNA adducts were analyzed by (32)P-postlabelling with nuclease P1 enrichment. PM10 concentrations were 36.9 microg/m(3), 62.6mug/m(3) and 39.0 microg/m(3), in summer 2000, winter 2001 and winter 2005, respectively. The corresponding EOM contents were 5.0 microg/m(3) (13.9% of PM10), 14.9 microg/m(3) (23.8%) and 6.7 microg/m(3) (17.2%). The total DNA adduct levels induced by 10 microg EOM/ml were 4.7, 19.5 and 37.2 adducts/10(8) nucleotides in summer 2000, winter 2001 and winter 2005, respectively. However, when the EOM quantities per cubic meter of air were taken into consideration, the summer sample exhibited a 10-fold lower genotoxicity than did those of winter, while the difference between the winter samples was not significant: 23.4 in summer 2000, 291 in winter 2001 and 249 in winter 2005 (in relative units). Although the PM10 concentration in air and the EOM content in particles in winter 2005 were significantly lower than in winter 2001, the genotoxic potential of the ambient air in these samples was almost equal. There were significant positive correlations between the B[a]P and c-PAH content in EOM from various sampling periods and the total DNA adduct levels detected in the EOM-treated samples. These findings support the hypothesis that the B[a]P and c-PAH content in EOM is the most important factor that determines its genotoxic potential. Thus, estimating the genotoxic potential of the ambient air and predicting health risk should be based mainly on the c-PAH concentration and the biological activity of the extracts, while the mass of particles and the EOM content do not seem to be crucial determinants of ambient air genotoxicity.     

长爪沙鼠免疫功能、体脂含量和器官重量的季节变化

小型哺乳动物的体脂含量与免疫功能有关,并受环境条件的影响。为了进一步理解野生长爪沙鼠对环境的生存适应策略,我们于2004 年夏季(7～8月)和2005年冬季(1～3月)测定了野生长爪沙鼠的体重、体脂含量和脏器重量,以及由匙孔血蓝蛋白(KLH)对雄鼠所介导的体液免疫反应。结果发现:雄鼠的胴体干重和体脂含量都显著高于雌鼠,其他各项指标无性别差异。冬季雌雄沙鼠的体重、胴体干重、体脂含量和褐色脂肪组织的湿重,以及雄鼠的睾丸湿重都显著高于夏季。脾脏的重量冬季趋于降低。处理组(注射KLH )动物血清中抗KLH 抗体的含量在冬季和夏季都显著高于对照组(注射生理盐水),且冬季处理组显著高于夏季处理组。本研究结果为动物种群调节的“冬季免疫增强假说”提供了一个新的野外例证。没有检测到免疫器官和产热器官、免疫器官和繁殖器官之间的权衡关系。     

Acoustic fish biomass assessment in a deep Tunisian reservoir: effects of season and diel rhythm on survey results

To determine the best acoustic sampling period for obtaining fish biomass estimates of a Mediterranean deep reservoir in Tunisia, day and night surveys were performed in spring (April), summer (September), autumn (December) and winter (March). A Simrad EK60 echosounder, equipped with two 120 kHz split-beam transducers for simultaneous horizontal and vertical beaming, was used to sample the entire water column. Data collected in December were not usable, because fish merged with methane gas bubbles. However, fish abundance varied across the other seasons, with a peak in acoustic biomass during summer nighttime hours associated with high water temperatures. Across seasons, the fish occupied the entire water column and fish schools were rarely observed. The preferential timeframe (i.e. maximum fish detectability and low gas flux) for acoustic sampling was nighttime hours in summer and daytime hours during spring and winter. Our findings highlight the importance of collecting data across seasons and photoperiods when determining an acoustic sampling strategy.     

Seasonal variability of dry matter content and its relationship with shoot growth and nonstructural carbohydrates

This study assesses how different phases of shoot growth underlie seasonal change in leaf and stem dry matter content (LDMC and SDMC, respectively) of 12 woody Mediterranean species. The relationship between LDMC and nonstructural carbohydrate (NSC) concentrations is also explored and the seasonal vs interspecies variability of LDMC compared. LDMC, SDMC and shoot elongation rate (SER) were measured on a monthly basis for a minimum of 12 months. Bud growth rate (BGR) and NSC concentrations were also assessed in several of the study species. LDMC and SDMC decreased during shoot elongation in spring and increased in summer, showing a significant negative correlation with SER, but were unrelated to BGR. Half of the species analysed showed a positive relationship between LDMC and NSC. Seasonal fluctuations of LDMC within species were higher than interspecies differences, and species ranking was significantly affected by the month of sampling, except during winter months. Seasonal changes in LDMC and SDMC are mainly related to shoot elongation phenology, and NSC sink-source relationships between old and growing organs can explain this relationship in some species. Owing to the high seasonal variability in LDMC, it is recommended that samples for comparative purposes should be collected as close to the winter as possible.     

长爪沙鼠褐色脂肪组织和肝脏产热特征的季节性变化

长爪沙鼠（Meriones unguiculatus）是一种栖息于典型草原和荒漠草原非冬眠群居性的小型哺乳动物。为研究其产热功能的季节变化,我们分别在2003年秋季（9月下旬）、冬季（11月下旬）、2004年春季（3月底-4月下旬）和夏季（7月下旬）,分别测定了其体重、褐色脂肪组织和肝脏的重量、线粒体总蛋白含量和细胞色素c氧化酶活力,以及褐色脂肪组织中解偶联蛋白1（Uncoupling protein1,UCPl）的含量等。结果显示：除雄鼠的体重显著高于雌鼠外,其它各项指标均无性别差异。体重和褐色脂肪组织的重量都在冬季较高,显著高于夏季,而肝脏的重量在夏季显著高于其它季节。褐色脂肪组织和肝脏的线粒体蛋白含量和细胞色素c氧化酶活力以及UCP1含量,都在冬季较高,夏季较低。这些结果表明：在野外条件下,褐色脂肪组织和肝脏在细胞水平上产热能力的提高和UCP1含量的增加,是长爪沙鼠抵御寒冷的重要方式。