城市水环境承载力及其实证研究

采用系统研究方法，对城市水环境承载力的概念、实质、功能及定量表达方法作出了分析，并利用系统动力学模拟手段进行了实证研究，利用水环境承载力指数变化对拟定的调整策略变量作出了预测、优化，得出了较满意的结论。     

多溴联苯醚的环境毒理学研究进展

多溴联苯醚(PBDEs)是一类广泛使用的溴代阻燃剂,其大量生产和使用导致了越来越严重的环境污染.由于PBDEs具有较高的亲脂性,化学性质比较稳定,它们可远距离传输到地球各种环境介质中,并通过食物链累积放大,在生物体内蓄积产生毒性效应.本文针对近年来PBDEs毒性效应和致毒机制的研究进展,从PBDEs的内分泌干扰毒性、发...     

大鼠胚胎期PFOS暴露致出生早期死亡及神经系统发育影响的基因组学分析

为了阐明PFOS导致新生儿死亡的可能原因和机制,探讨PFOS致死与神经系统发育的相互联系,利用基因芯片技术,观察了经PFOS饲料染毒后出生1和7d大鼠脑组织基因表达情况,通过基因组学(Gene Ontology)和生物路径(Pathway)对差异基因的功能和相互联系进行分析.结果显示,PFOS染毒后,出生1、7d的大鼠脑皮质组织分别有864、642条基因发生差异表达,差异基因涉及的与PFOS致死相关的生物过程包括中枢神经系统发育、血循环系统、刺激应答、骨骼发育、氧化应激、心脏功能以及pH值调节等.结果表明,PFOS导致的出生早期死亡与神经系统发育有关,PFOS可能通过改变脑组织血氧平衡,影响正常的中枢神经系统功能和发育过程而使新生儿的存活率下降.     

应用黑斑蛙胚胎测试化学品发育毒性的方法

选择合适的尤其是本土生物种进行化学品生态毒性评估,对于各国化学品的环境管理十分重要.本文选择我国本土两栖种黑斑蛙的胚胎为试验生物,以半数致死浓度LC50、半数致畸浓度TC50、致畸指数TI及最小抑制生长浓度MCIG为终点指标,建立了黑斑蛙胚胎发育毒性试验方法.以五氯酚、视磺酸、氯化镉、重铬酸钾为测试物研究了方法的敏感性,并以五氯酚为测试物研究了方法的可重复性.结果显示:五氯酚、视磺酸、氯化镉和重铬酸钾对黑斑蛙胚胎的LC50分别为572.3 μg·L-1、54.8 μg·L-1、6.8 mg·L-1和97.5 mg· L-1.五氯酚、视磺酸和氯化镉对黑斑蛙胚胎的TC50分别为246.5 μg·L-1、18.7 μg· L-1和3.4 mg·L-1,TI分别为2.3、2.9和2.0,MCIG分别为160.0 μg· L-1、10.1 μg·L-1和2.4 mg·L-1.重复性试验发现,五氯酚的LC50、TC50、TI及MCIG的变异系数分别为12.6％、18.0％、23.0％和18.6％.与文献中非洲爪蟾胚胎试验的数据比较,这些数据显示黑斑蛙胚胎与非洲爪蟾胚胎对测试物的敏感性存在一定的差异,各个终点指标的变异系数相当.因此,本文建立的黑斑蛙胚胎发育毒性试验可以用于化学品的发育毒性评价,为我国化学品环境管理提供技术支持.     

nano-ZnO对斑马鱼鱼鳔发育毒性效应研究

根据鱼鳔发育的不同阶段,从受精后0 h(0 hours post fertilization, 0 hpf)开始对5个发育阶段(0 hpf～孵化前、0～120 hpf、0～168 hpf、孵化后～120 hpf、120～168 hpf)的斑马鱼进行nano-ZnO暴露实验,研究不同浓度的nano-ZnO对斑马鱼鱼鳔的影响.结果表明,nano-ZnO悬浮液中溶解的Zn~(2+)不是导致斑马鱼死亡和鱼鳔缺损的唯一或主要原因.nano-ZnO暴露浓度越高,斑马鱼的死亡率和鱼鳔缺损率越高,存在剂量-效应关系.15 mg·L~(-1) nano-ZnO可造成90%的斑马鱼鱼鳔缺损和死亡,10 mg·L~(-1) nano-ZnO可导致斑马鱼鱼鳔面积缩小70%.斑马鱼鱼鳔早期发育阶段(0～168 hpf)对nano-ZnO敏感度大小为:出芽阶段(0 hpf～孵化前)充气阶段(孵化后～120 hpf)充气完成阶段(120～168 hpf).斑马鱼鱼鳔的发育面积和发育时间也受nano-ZnO暴露染毒的影响而发生变化.斑马鱼死亡率和鱼鳔缺损率(鱼鳔发育)之间存在相关性(r=0.978,p0.01).这表明斑马鱼鱼鳔的发育缺损是造成斑马鱼胚胎死亡的主要原因之一,但nano-ZnO对斑马鱼鱼鳔的影响机理,尤其是对鱼鳔出芽阶段和充气阶段的致毒机理需要进一步研究.     

Ontogeny and Population: Developmental Stability and Population Variation

By definition, the ontogenetic and population organization levels are fundamentally different. Studies at these levels are traditionally independent. However, it becomes increasingly evident that special analysis of individuals in terms of ontogeny is necessary for correct estimation of populations and their spatiotemporal dynamics, as well as for understanding the mechanisms of population processes.     

Phenogenetic monitoring of the weeping birch (<Emphasis Type="Italic">Betula pendula</Emphasis> Roth.) in the Middle Urals: testing a new method for assessing developmental instability in higher plants

Variation of bilateral leaf structures in Middle Ural cenopopulations of the weeping birch (Betula pendula Roth.) growing in gradients of industrial pollution was studied to test the efficiency of a new method of population and individual phenogenetic monitoring allowing an indirect assessment of developmental destabilization by segregating the variance of total asymmetry (TA _R ²) into its additive components, the variances of fluctuating asymmetry (FA _R ²) and directional asymmetry (DA _R ²). The method was tested in the impact zones of two copper-smelting plants in the Middle Urals. The degree of impact was characterized by the index of technogenic pollution (ITP) reflecting the average total contents of 15 water-soluble pollutants in snow samples. The level of asymmetry was estimated from the numbers of denticles with incoming veins (dentovenal elements) on the left and right leaf margins. Spearman’s coefficient of rank correlation between the group values of variance in fluctuating asymmetry (FA _R ²) and corresponding ITP values reached r _S = 0.914 (p < 0.001), providing evidence that the method is highly appropriate for ecological indication of the phenogenetic response of trees to environmental pollution.     

Relationships between developmental instability in morphological characters and fitness of <Emphasis Type="Italic">Aphis fabae</Emphasis> population reared on two host plants

Fluctuating asymmetry (FA) and the coefficient of within-environment variation (CV _e) are often used as measures of developmental instability and indicators of developmental deviations. Aphis fabae genotypes generally manifest higher developmental instability on novel host plants, but there is genotypic variability in this respect. Some genotypes have manifested lower developmental instability on nasturtium, where their fitness is higher. At the population level, aphids reared on nasturtium have shown higher developmental instability and lower fitness. When large samples are analyzed and the nonsignificant pattern of correlations is taken into account, the results of the study do not support the hypothesis that developmental instability is always a reliable indicator of fitness. Published in Russian in Ekologiya, 2007, Vol. 38, No. 2, pp. 131–136. The text was submitted by the authors in English.     

CdSe/ZnS量子点对斑马鱼胚胎发育的毒性效应

本研究以模式生物斑马鱼(Danio rerio)为对象,观察在不同浓度Cd Se/Zn S量子点(Cd Se/Zn S QDs)暴露下,斑马鱼胚胎形态发育、氧化应激以及金属硫蛋白MT基因和应激蛋白Hsp70基因表达变化情况.结果表明,Cd Se/Zn S QDs对斑马鱼胚胎72 hpf(hours post fertilization)的半致畸效应浓度(EC50)为316.994 nmol·L-1.QDs暴露影响了斑马鱼胚胎的死亡率、畸形率、孵化率、自主运动频率和体长,以及引起胚胎卵凝集,心包囊肿,脊椎弯曲等多种毒性效应;同时导致斑马鱼体内超氧化物歧化酶(SOD)活性变化以及丙二醛(MDA)含量增加.QDs还诱导斑马鱼MT基因和Hsp70基因表达上调,斑马鱼机体产生一系列自我保护反应来减轻QDs所造成的伤害.这表明:Cd Se/Zn S QDs对斑马鱼胚胎产生了毒性效应,其毒性可能与其核心Cd2+的释放、粒径大小以及氧化应激有关.     

T-2 toxin induces developmental toxicity and apoptosis in zebrafish embryos

T-2 toxin is one of the most important trichothecene mycotoxins occurring in various agriculture products. The developmental toxicity of T-2 toxin and the exact mechanism of action at early life stages are not understood precisely. Zebrafish embryos were exposed to different concentrations of the toxin at 4-6 hours post fertilization （hpf） stage of development, and were observed for different developmental toxic effects at 24, 48, 72, and 144 hpf. Exposure to 0.20 Ixmol/L or higher concentrations of T-2 toxin significantly increased the mortality and malformation rate such as tail deformities, cardiovascular defects and behavioral changes in early developmental stages of zebrafish. T-2 toxin exposure resulted in significant increases in reactive oxygen species （ROS） production and cell apoptosis, mainly in the tall areas, as revealed by Acridine Orange staining at 24 hpf. In addition, T-2 toxin-induced severe tail deformities could be attenuated by co-exposure to reduced glutathione （GSH）. T-2 toxin and GSH co-exposure induced a significant decrease of ROS production in the embryos. The overall results demonstrate that T-2 toxin is able to produce oxidative stress and induce apoptosis, which are involved in the developmental toxicity of T-2 toxin in zebrafish embryos.