四种环境激素对萼花臂尾轮虫生活史及生殖影响
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摘要
轮虫由于在水生态系统种群动态中起着重要作用,因此为水生态毒理学研究的模式生物,利用轮虫评价环境激素效应为世界关注的热点问题。本文以淡水水体中普遍存在的萼花臂尾轮虫(Brachionus calyciflorus)为受试动物,研究了4种环境激素双酚A(bisphenolA)、阿特拉津(atrazine)、西维因(carbaryl)和久效磷(monocrotophos)对萼花臂尾轮虫急性毒性、生活史、无性生殖与有性生殖影响。主要研究结果如下:
1、BPA对萼花臂尾轮虫24h急性毒性LC50值为13.76mg/L;慢性毒性表明,BPA对轮虫主要生活史阶段和生命表参数具有干扰作用,尤以有性生殖影响最为显著。生活史阶段显示,BPA浓度0.25-4.0mg/L对轮虫胚胎发育无显著影响,但BPA浓度2.0-4.0mg/L却显著延迟轮虫幼体发育时间,该浓度显著缩短轮虫生殖期和生殖后期时间;BPA浓度0.5mg/L显著增加轮虫净生殖率(Ro),浓度为2.0、4.0mg/L却显著降低R0,1.0mg/L对R0无显著影响;BPA浓度4.0mg/L显著降低世代时间(T);BPA浓度为2.0、4.0mg/L时显著降低轮虫生命期望值(e0);BPA浓度为1.0mg/L及以上浓度时,显著降低轮虫内禀增长率(rm);BPA浓度为0.5、1.0mg/L时显著增加轮虫所产后代混交率(MR);研究结果表明R0和MR受BPA影响最为显著。群体研究表明,BPA浓度为0.5、1.0mg/L显著降低轮虫2d的r,而浓度为0.313、0.0625、0.125及0.25mg/L对轮虫2d的r无显著影响;BPA浓度0.25mg/L及以上浓度显著降低轮虫3d的混交/非混交比率、混交率,0.125mg/L及以上浓度显著降低轮虫3d的受精率;休眠卵产量显示,0.125mg/L及以浓度显著降低轮虫7d的休眠卵产量,0.0625mg/L及以上浓度显著降低轮虫3d的休眠卵孵化率。综上所述,轮虫休眠卵孵化率对BPA最敏感,其次为休眠卵产量及受精率,以上指标可作为评价BPA环境激素较敏感指标。
2、阿特拉津对轮虫24h的LC50值为39.2mg/L,阿特拉津对轮虫的生活史及生殖具有显著影响。0.64-10.24mg/L的阿特拉津显著延长轮虫生殖前期历时,2.56-10.24mg/L阿特拉津延长胚胎发育历时,但缩短了轮虫生殖期历时和平均寿命;阿特拉津对轮虫生殖后期无显著影响;生命表参数显示,阿特拉津0.64-10.24mg/L显著降低轮虫rm,2.56-10.24mg/L时显著降低e0、R0,阿特拉津0.04-10.24mg/L对T无显著影响。阿特拉津对轮虫后代的影响表明,母体暴露在以上阿特拉津溶液下所产第1胎F1(1st)在正常溶液下培养,2.56-10.24mg/L下产生F1(1st)生殖前期、生殖期、寿命、e0和R0未恢复,0.64-10.24mg/L下所产的F1(1st)的rm未恢复;但在第2胎F1(2nd)中,除2.56-10.24mg/L所产后代rm未恢复,10.24mg/L的生殖前期、R0未恢复,其它指标都得到恢复,显示阿特拉津对轮虫后代具有潜在影响。
3、西维因对轮虫24h的LC5o为4.10mg/L,对其生活史研究表明,西维因1.6-2.0mg/L显著延长轮虫生殖前期时间,但缩短生殖期时间和平均寿命;1.2mg/L及以上浓度显著延长胚胎发育期,2.0mg/L缩短轮虫生殖后期时间。生命表参数显示,0.8-2.0mg/L显著降低R0和rm,1.2mg,/L及以上浓度显著降低轮虫世代时间和生命期望值。低剂量阿特拉津(0.02、0.08、0.32、1.28、5.12mg/L)和西维因(0.02、0.06、0.18、0.54、1.62mg/L)对萼花臂尾轮虫2d种群增长、3d有性生殖及7d休眠卵产量、3d休眠卵孵化率有显著影响,实验结果表明,与对照组相比,阿特拉津5.12mg/L、西维因1.62mg/L显著降低轮虫2d的r;阿特拉津1.28、5.12mg/L显著降低混交率,受精率;西维因除0.06mg/L显著增加OF/NOF值外,其它浓度对OF/NOF无显著影响,0.06mg/L的西维因显著增加轮虫混交率,0.54、1.62mg/L西维因显著降低混交率;轮虫7d休眠卵产量及孵化率表明,阿特拉津0.32-5.12mg/L显著降低轮虫休眠卵产量和孵化率,西维因0.18-1.62mg/L降低休眠卵产量,西维因0.06-1.62mg/L显著降低休眠孵化率,显示轮虫休眠卵孵化率对阿特拉津和西维因最敏感。
4、久效磷对轮虫24h急性毒性LC5o值为5.65mg/L,久效磷对轮虫生活史及生殖具有显著影响。生活史研究表明,0.5-2.0mg/L显著延长轮虫生殖前期时间、总产卵量,1.0-2.0mg/L显著缩短轮虫生殖期、生殖后期和平均寿命;0.5-2.0mg/L降低R0及rm,。群体培养表明,0.5mg/L降低轮虫3d的种群增长率,0.25mg/L可降低轮虫3d的混交率,0.125-0.5mg/L时显著降低休眠卵产量,0.0625-0.5mg/L久降低休眠卵孵化率,因此轮虫休眠卵孵化率对久效磷敏感性最高。
5、阿特拉津(0.02、0.08mg/L)和久效磷(0.0079、0.0157、0.0313mg/L)单独对轮虫2d的r,4d的MR、OF/NOF、FR及7d的休眠卵产量无显著影响,但当阿特拉津和久效磷混合时,轮虫以上生殖指标部分受到交互影响,影响程度主要取决于2种环境激素的浓度;阿特拉津最高浓度与久效磷最高浓度混合作用对轮虫生殖影响最显著,而两者以最低浓度相混合对轮虫生殖指标无显著影响,其它浓度相混合对轮虫生殖影响介于最高与最低之间。阿特拉津与久效磷复合对轮虫生殖影响以休眠卵产量影响最为显著。研究表明,单一环境激素对轮虫生殖影响不能全面地用来评价环境激素效应,因为两种或以上环境激素复合可能对轮虫生殖产生影响,因此在水生态研究中必须关注环境激素对轮虫生殖的复合影响。
Rotifers are useful as models in ecotoxicology because they play an important in the freshawater and marine ecosystems. Using the rotifer to evaluate environmental hormone effect is a worldwide concern. The effects of bisphenol A (BPA), atrazine, carbaryl and monocrotophos on the acute test, life history, asexual and sexual reproduction of Brachionus.calyciflorus were studied. The main results were presented as the following:
1. The effect of BPA on the acute toxicity (24hLC50) of BPA for B. calyciflorus was13.76mg/L. BPA had a significant interference effect on the life stage and life table parameter, especially on the effect of sexual reproduction. In the life history test, the tested concentration0.25-4.0mg/L had no significant effect on the embryonic development compared to the control, BPA at2.0and4.0mg/L extended significantly the durations of juvenile development than the control, but shortened the reproductive period and post-reproductive period. BPA at0.5mg/L increased significantly net reproduction rate (Ro) compared the control. But BPA at2.0and4.0mg/L decreased significantly the Ro, and BPA at4.0mg/L reduced the generation time (7). BPA from1.0to4.0mg/L decreased significantly the intrinsic rate of increase (rm), the mix rate of total offsprings was increased markedly at0.5and1.0mg/L than the control. The results showed that different endpoints of both development and reproduction had different sensitivity to BPA. Ro and mixis rate endpoint of the rotifers appeared to be more sensitive than other endpoints. The effects of BPA (0.313,0.0625,0.125,0.25,0.5,1.0mg/L) on the population growth rate (r) of rotifer at2d showed that BPA at0.5,1.0mg/L reduced markedly the r, other concentration did not affect the r. The reproduction of3d indicated that BPA from0.25mg/L to1.0mg/L decreased significantly the mictic female/amictic female (MF/AF), mix rate (MR) than the control. At the same time, BPA from0.125mg/L reduced the fertilization rate (FR). The resting egg (RE) production at7d showed that the BPA from0.125mg/L reduced the RE production, and0.0625mg/L and above decreased significantly the resting egg hatching rate at3d. All these results indicated that resting egg hatching rate were most sensitive parameter and resting egg production, fertilization rate were second to assess environmental hormone effect of BPA.
2.24h median lethal concentration (24h LC50) value of atrazine for B. calyciflorus were39.2mg/L. life history (rotifer exposed atrazine0.04-10.24mg/L) showed that atrazine from0.64to10.24mg/L significantly pronged pre-reproductive period (JP) compared to the control, atrazine from2.56to10.24mg/L extended significantly the embryonic development time, but reduced significantly the reproduction period and mean life span. Atrazine did not affect the post reproduction period of rotifer. Life table showed that atrazine from0.64mg/L to10.24mg/L decreased significantly the rm,2.56-10.24mg/L reduced markedly the eo and R0, the concentration from0.04mg/L to10.24mg/L had no effect on the Tthan the control. The recovery of rotifer exposed atrazine concentration showed that the first rotifer(1st) produced from mother rotifer(Fo) raised at free atrazine, first brood F1(1st) produced by Fo exposed from2.56and10.24mg/L had no significant effect on pre-reproductive period(PP), reproduction period (RP), mean life (ML), e0and Ro, but from the second brood F1(2nd) from the Fo exposed atrazine all the parameter had been recovered except rm of rotifer produced from the F0exposed2.56-10.24mg/L, PP, Ro of F1(2nd) produced from the mother female (Fo) exposed10.24mg/L had not been recovered, all these results showed that atrazine had potential effect on the offsprings.
3. Acute toxicity of carbaryl on the rotifer24h LC50was4.10mg/L. Carbaryl from1.6to2.0mg/L extended the pre-reproductive period (JP), but reduced the PP and ML, concentration from1.2mg/L to2mg/L extended significantly embryonic development time (EP),2.0mg/L decreased markedly PP. Life table showed carbaryl from0.8to2.0mg/L decreased significantly Ro and rm, concentration from1.2mg/L reduced significantly T and e0.
Effect of rotifer populations were exposed to atrazine at low concentrations from0to5.12mg/L and carbaryl from0.02mg/L to1.62mg/L, the2-d population growth rate,3-d reproduction parameter,7-d resting egg production (RE), and3-d resting egg hatching rate (HR) were measured. The results showed that atrazine concentration had effect on the mix rate, male number and fertilization rate, and no effect on OF/NOF. The no effect concentration (NOEC) and lowest effect concentration (LOEC) of atrazine were1.28mg/L and5.12mg/L for population growth rate (r), and for carbaryl were0.54mg/L and1.62mg/L. In sexual reproduction, the NOEC and LOEC of atrazine for MR were0.32and1.28mg/L. However, carbaryl did not show similar results because0.06mg/L carbaryl increased the MR compared with the control. The NOEC and LOEC of atrazine for RE and HR were the same (0.08and0.32mg/L) and the NOEC and LOEC of carbaryl for RE were slightly lower. HR was the most sensitive of all indices with NOEC and LOEC of atrazine from0.02to0.32mg/L nominal concentration. The result showed that the resting egg hatching rate was the most sensitive parameter to atrazine and carbaryl.
4. Effect of monocrotophos on the life history and reproduction of rotifer were investigated. The24h median lethal concentration value was5.65mg/L. Life history indicated monocrotophos from0.25to2.0mg/L prolonged significantly pre-reproduction period, total eggs, Ro and rm,1.0-2.0mg/L reduced markedly the RP, PP and ML. The results of3d population growth test showed that monocrotophos at0.5mg/L reduced the r,0.25mg/L decreased significantly the mix rate, but had no effect on the fertilization rate, concentration from0.125to0.5mg/L decreased significantly the resting egg production,0.0625-0.5mg/L decreased markedly the resting egg hataching rate. The results showed that resting egg hating rate was the most parameter, and discovered that the fertilization rate sometimes was not the more sensitive parameter than other reproductive parameters.
5. Atrazine (0,0.02,0.08mg/L) and monocrotophos(Mop)(0、0.0079、0.0157、0.0313mg/L) had no significant effect on r at2d, MR, OF/NOF, FR at4d, resting egg production at7d of rotifer respectively. But atrazine mixed Mop at different concentrations, the reproductive parameters of rotifer had been affected depended on the concentrations of atrazine and Mop concentration. Atrazine at0.08mg/L mixed Mop at0.0313mg/L had significnt effect on reproduction of rotifer. But atrazine at lowerst concnentration mixed Mop at lowerest concentration had no significant effect on the reproduction of rotifer compared the control. Other concentrations mixed affected the reproduction of rotifer between the lowest and highest concentrations. Compound effect of atrazine and mop on the resting egg production in all reproductive indicides is the most sensitive. The results showed that simple environment hormone could not assess the envirnonmental effect on rotifer fully, but when different environmental hormone mixed, they could affect the reproduction of rotifer. The results showed that the simple environmental hormone might not affect the reproduction of rotifer, but different environmental hormone combined, the reproduction of rotifer might be affected.
1、BPA对萼花臂尾轮虫24h急性毒性LC50值为13.76mg/L;慢性毒性表明,BPA对轮虫主要生活史阶段和生命表参数具有干扰作用,尤以有性生殖影响最为显著。生活史阶段显示,BPA浓度0.25-4.0mg/L对轮虫胚胎发育无显著影响,但BPA浓度2.0-4.0mg/L却显著延迟轮虫幼体发育时间,该浓度显著缩短轮虫生殖期和生殖后期时间;BPA浓度0.5mg/L显著增加轮虫净生殖率(Ro),浓度为2.0、4.0mg/L却显著降低R0,1.0mg/L对R0无显著影响;BPA浓度4.0mg/L显著降低世代时间(T);BPA浓度为2.0、4.0mg/L时显著降低轮虫生命期望值(e0);BPA浓度为1.0mg/L及以上浓度时,显著降低轮虫内禀增长率(rm);BPA浓度为0.5、1.0mg/L时显著增加轮虫所产后代混交率(MR);研究结果表明R0和MR受BPA影响最为显著。群体研究表明,BPA浓度为0.5、1.0mg/L显著降低轮虫2d的r,而浓度为0.313、0.0625、0.125及0.25mg/L对轮虫2d的r无显著影响;BPA浓度0.25mg/L及以上浓度显著降低轮虫3d的混交/非混交比率、混交率,0.125mg/L及以上浓度显著降低轮虫3d的受精率;休眠卵产量显示,0.125mg/L及以浓度显著降低轮虫7d的休眠卵产量,0.0625mg/L及以上浓度显著降低轮虫3d的休眠卵孵化率。综上所述,轮虫休眠卵孵化率对BPA最敏感,其次为休眠卵产量及受精率,以上指标可作为评价BPA环境激素较敏感指标。
2、阿特拉津对轮虫24h的LC50值为39.2mg/L,阿特拉津对轮虫的生活史及生殖具有显著影响。0.64-10.24mg/L的阿特拉津显著延长轮虫生殖前期历时,2.56-10.24mg/L阿特拉津延长胚胎发育历时,但缩短了轮虫生殖期历时和平均寿命;阿特拉津对轮虫生殖后期无显著影响;生命表参数显示,阿特拉津0.64-10.24mg/L显著降低轮虫rm,2.56-10.24mg/L时显著降低e0、R0,阿特拉津0.04-10.24mg/L对T无显著影响。阿特拉津对轮虫后代的影响表明,母体暴露在以上阿特拉津溶液下所产第1胎F1(1st)在正常溶液下培养,2.56-10.24mg/L下产生F1(1st)生殖前期、生殖期、寿命、e0和R0未恢复,0.64-10.24mg/L下所产的F1(1st)的rm未恢复;但在第2胎F1(2nd)中,除2.56-10.24mg/L所产后代rm未恢复,10.24mg/L的生殖前期、R0未恢复,其它指标都得到恢复,显示阿特拉津对轮虫后代具有潜在影响。
3、西维因对轮虫24h的LC5o为4.10mg/L,对其生活史研究表明,西维因1.6-2.0mg/L显著延长轮虫生殖前期时间,但缩短生殖期时间和平均寿命;1.2mg/L及以上浓度显著延长胚胎发育期,2.0mg/L缩短轮虫生殖后期时间。生命表参数显示,0.8-2.0mg/L显著降低R0和rm,1.2mg,/L及以上浓度显著降低轮虫世代时间和生命期望值。低剂量阿特拉津(0.02、0.08、0.32、1.28、5.12mg/L)和西维因(0.02、0.06、0.18、0.54、1.62mg/L)对萼花臂尾轮虫2d种群增长、3d有性生殖及7d休眠卵产量、3d休眠卵孵化率有显著影响,实验结果表明,与对照组相比,阿特拉津5.12mg/L、西维因1.62mg/L显著降低轮虫2d的r;阿特拉津1.28、5.12mg/L显著降低混交率,受精率;西维因除0.06mg/L显著增加OF/NOF值外,其它浓度对OF/NOF无显著影响,0.06mg/L的西维因显著增加轮虫混交率,0.54、1.62mg/L西维因显著降低混交率;轮虫7d休眠卵产量及孵化率表明,阿特拉津0.32-5.12mg/L显著降低轮虫休眠卵产量和孵化率,西维因0.18-1.62mg/L降低休眠卵产量,西维因0.06-1.62mg/L显著降低休眠孵化率,显示轮虫休眠卵孵化率对阿特拉津和西维因最敏感。
4、久效磷对轮虫24h急性毒性LC5o值为5.65mg/L,久效磷对轮虫生活史及生殖具有显著影响。生活史研究表明,0.5-2.0mg/L显著延长轮虫生殖前期时间、总产卵量,1.0-2.0mg/L显著缩短轮虫生殖期、生殖后期和平均寿命;0.5-2.0mg/L降低R0及rm,。群体培养表明,0.5mg/L降低轮虫3d的种群增长率,0.25mg/L可降低轮虫3d的混交率,0.125-0.5mg/L时显著降低休眠卵产量,0.0625-0.5mg/L久降低休眠卵孵化率,因此轮虫休眠卵孵化率对久效磷敏感性最高。
5、阿特拉津(0.02、0.08mg/L)和久效磷(0.0079、0.0157、0.0313mg/L)单独对轮虫2d的r,4d的MR、OF/NOF、FR及7d的休眠卵产量无显著影响,但当阿特拉津和久效磷混合时,轮虫以上生殖指标部分受到交互影响,影响程度主要取决于2种环境激素的浓度;阿特拉津最高浓度与久效磷最高浓度混合作用对轮虫生殖影响最显著,而两者以最低浓度相混合对轮虫生殖指标无显著影响,其它浓度相混合对轮虫生殖影响介于最高与最低之间。阿特拉津与久效磷复合对轮虫生殖影响以休眠卵产量影响最为显著。研究表明,单一环境激素对轮虫生殖影响不能全面地用来评价环境激素效应,因为两种或以上环境激素复合可能对轮虫生殖产生影响,因此在水生态研究中必须关注环境激素对轮虫生殖的复合影响。
Rotifers are useful as models in ecotoxicology because they play an important in the freshawater and marine ecosystems. Using the rotifer to evaluate environmental hormone effect is a worldwide concern. The effects of bisphenol A (BPA), atrazine, carbaryl and monocrotophos on the acute test, life history, asexual and sexual reproduction of Brachionus.calyciflorus were studied. The main results were presented as the following:
1. The effect of BPA on the acute toxicity (24hLC50) of BPA for B. calyciflorus was13.76mg/L. BPA had a significant interference effect on the life stage and life table parameter, especially on the effect of sexual reproduction. In the life history test, the tested concentration0.25-4.0mg/L had no significant effect on the embryonic development compared to the control, BPA at2.0and4.0mg/L extended significantly the durations of juvenile development than the control, but shortened the reproductive period and post-reproductive period. BPA at0.5mg/L increased significantly net reproduction rate (Ro) compared the control. But BPA at2.0and4.0mg/L decreased significantly the Ro, and BPA at4.0mg/L reduced the generation time (7). BPA from1.0to4.0mg/L decreased significantly the intrinsic rate of increase (rm), the mix rate of total offsprings was increased markedly at0.5and1.0mg/L than the control. The results showed that different endpoints of both development and reproduction had different sensitivity to BPA. Ro and mixis rate endpoint of the rotifers appeared to be more sensitive than other endpoints. The effects of BPA (0.313,0.0625,0.125,0.25,0.5,1.0mg/L) on the population growth rate (r) of rotifer at2d showed that BPA at0.5,1.0mg/L reduced markedly the r, other concentration did not affect the r. The reproduction of3d indicated that BPA from0.25mg/L to1.0mg/L decreased significantly the mictic female/amictic female (MF/AF), mix rate (MR) than the control. At the same time, BPA from0.125mg/L reduced the fertilization rate (FR). The resting egg (RE) production at7d showed that the BPA from0.125mg/L reduced the RE production, and0.0625mg/L and above decreased significantly the resting egg hatching rate at3d. All these results indicated that resting egg hatching rate were most sensitive parameter and resting egg production, fertilization rate were second to assess environmental hormone effect of BPA.
2.24h median lethal concentration (24h LC50) value of atrazine for B. calyciflorus were39.2mg/L. life history (rotifer exposed atrazine0.04-10.24mg/L) showed that atrazine from0.64to10.24mg/L significantly pronged pre-reproductive period (JP) compared to the control, atrazine from2.56to10.24mg/L extended significantly the embryonic development time, but reduced significantly the reproduction period and mean life span. Atrazine did not affect the post reproduction period of rotifer. Life table showed that atrazine from0.64mg/L to10.24mg/L decreased significantly the rm,2.56-10.24mg/L reduced markedly the eo and R0, the concentration from0.04mg/L to10.24mg/L had no effect on the Tthan the control. The recovery of rotifer exposed atrazine concentration showed that the first rotifer(1st) produced from mother rotifer(Fo) raised at free atrazine, first brood F1(1st) produced by Fo exposed from2.56and10.24mg/L had no significant effect on pre-reproductive period(PP), reproduction period (RP), mean life (ML), e0and Ro, but from the second brood F1(2nd) from the Fo exposed atrazine all the parameter had been recovered except rm of rotifer produced from the F0exposed2.56-10.24mg/L, PP, Ro of F1(2nd) produced from the mother female (Fo) exposed10.24mg/L had not been recovered, all these results showed that atrazine had potential effect on the offsprings.
3. Acute toxicity of carbaryl on the rotifer24h LC50was4.10mg/L. Carbaryl from1.6to2.0mg/L extended the pre-reproductive period (JP), but reduced the PP and ML, concentration from1.2mg/L to2mg/L extended significantly embryonic development time (EP),2.0mg/L decreased markedly PP. Life table showed carbaryl from0.8to2.0mg/L decreased significantly Ro and rm, concentration from1.2mg/L reduced significantly T and e0.
Effect of rotifer populations were exposed to atrazine at low concentrations from0to5.12mg/L and carbaryl from0.02mg/L to1.62mg/L, the2-d population growth rate,3-d reproduction parameter,7-d resting egg production (RE), and3-d resting egg hatching rate (HR) were measured. The results showed that atrazine concentration had effect on the mix rate, male number and fertilization rate, and no effect on OF/NOF. The no effect concentration (NOEC) and lowest effect concentration (LOEC) of atrazine were1.28mg/L and5.12mg/L for population growth rate (r), and for carbaryl were0.54mg/L and1.62mg/L. In sexual reproduction, the NOEC and LOEC of atrazine for MR were0.32and1.28mg/L. However, carbaryl did not show similar results because0.06mg/L carbaryl increased the MR compared with the control. The NOEC and LOEC of atrazine for RE and HR were the same (0.08and0.32mg/L) and the NOEC and LOEC of carbaryl for RE were slightly lower. HR was the most sensitive of all indices with NOEC and LOEC of atrazine from0.02to0.32mg/L nominal concentration. The result showed that the resting egg hatching rate was the most sensitive parameter to atrazine and carbaryl.
4. Effect of monocrotophos on the life history and reproduction of rotifer were investigated. The24h median lethal concentration value was5.65mg/L. Life history indicated monocrotophos from0.25to2.0mg/L prolonged significantly pre-reproduction period, total eggs, Ro and rm,1.0-2.0mg/L reduced markedly the RP, PP and ML. The results of3d population growth test showed that monocrotophos at0.5mg/L reduced the r,0.25mg/L decreased significantly the mix rate, but had no effect on the fertilization rate, concentration from0.125to0.5mg/L decreased significantly the resting egg production,0.0625-0.5mg/L decreased markedly the resting egg hataching rate. The results showed that resting egg hating rate was the most parameter, and discovered that the fertilization rate sometimes was not the more sensitive parameter than other reproductive parameters.
5. Atrazine (0,0.02,0.08mg/L) and monocrotophos(Mop)(0、0.0079、0.0157、0.0313mg/L) had no significant effect on r at2d, MR, OF/NOF, FR at4d, resting egg production at7d of rotifer respectively. But atrazine mixed Mop at different concentrations, the reproductive parameters of rotifer had been affected depended on the concentrations of atrazine and Mop concentration. Atrazine at0.08mg/L mixed Mop at0.0313mg/L had significnt effect on reproduction of rotifer. But atrazine at lowerst concnentration mixed Mop at lowerest concentration had no significant effect on the reproduction of rotifer compared the control. Other concentrations mixed affected the reproduction of rotifer between the lowest and highest concentrations. Compound effect of atrazine and mop on the resting egg production in all reproductive indicides is the most sensitive. The results showed that simple environment hormone could not assess the envirnonmental effect on rotifer fully, but when different environmental hormone mixed, they could affect the reproduction of rotifer. The results showed that the simple environmental hormone might not affect the reproduction of rotifer, but different environmental hormone combined, the reproduction of rotifer might be affected.
引文
[1]Colborn T, vom Saal F S, Soto A M. Developmental effects of endocrine-disrupting chemicals in wildlife and humans[J]. Environ Health Perspect,1993,101(5):378-384.
[2]Harrison P T, Holmes P, Humfrey C D. Reproductive health in humans and wildlife:are adverse trends associated with environmental chemical exposure?[J]. Sci Total Environ,1997,205(2-3):97-106.
[3]周少奇,林云琴.环境激素污染研究进展[J].环境污染与防治,2004,26(1):25-27.
[4]包国章,董德明,李向林.环境雌激素生态影响的研究进展[J].生态学杂志,200 1,20(5):44-50.
[5]Magliulo L, Schreibman M P, Cepriano J e a. Endocrine disruption caused by two common pollutants at "acceptable"concentrations[J]. Neurotoxicology and Teratology,2002, (24):71-79.
[6]Takahashi, Higashitani, Yakou e a. Evaluating bioaccumulation of suspected endocrine disruptors into periphytons and benthos in the Tama River[J]. Water Science and Technology,2003,47(9):71-83.
[7]Zou E. Current status of environmental endocrine disruptionin selected aquatic invertebrates[J]. Acta Zoologica Sinica,,2003,49(5):551-565.
[8]Colborn T. Environmental estrogens:health implications for humans and wildlife[J]. Environmental Health Perspectives,1995,103(Suppl 7):135.
[9]杨再福,赵晓祥.环境雌激素对水生动物的影响研究进展[J].生态环境,2005,14(1):108-112.
[10]王杉霖,张剑波.中国环境内分泌干扰物的污染现状分析[J].环境污染与防治,2005,27(3):228-231.
[11]王毓秀,张利民,邹敏.化学农药与环境激素[J].农村生态环境,1999,15(4):37-41.
[12]刘玉成,刘玉斌,李太福.城市固体垃圾焚烧的二次污染控制实现技术[J].环境科学与技术,2006,29(5):97-99.
[13]刘苹.环境激素与人类健康[J].云南环境科学,2001,20(z1):42-45.
[14]薛南冬,王洪波,徐晓白.水环境中农药类内分泌干扰物的研究进展[J].科学通报,2005,50(22):2441-2449.
[15]任仁.环境激素的种类和污染途径[J].大学化学,2001,16(5):28-32.
[16]章志青.环境激素对人体健康的影响及其防制对策[J].绍兴文理学院学报,2004,24(7):109-112.
[17]McKinlay R, Plant J A, Bell J N B, et al. Endocrine disrupting pesticides: Implications for risk assessment[J]. Environment International,2008,34(2): 168-183.
[18]刘现明,徐学仁,张笑天,等.大连湾沉积物中的有机氯农药和多氯联苯[J].海洋环境科学,2001,20(4):40-44.
[19]魏渲辉,汝少国,姜明.有机磷农药对鱼类的毒性效应及内分泌扰乱作用[J].海洋科学,2002,26(9):27-31.
[20]邹晓平,杨丽,秦红,等.农村男性接触有机磷农药对精液质量影响的研究[J].中国计划生育学杂志,2006,13(8):476-478.
[21]王凌一,黎先春,殷月芬,等.菜州湾水体中有机磷农药的残留监测与风险影响评价[J].安全与环境学报,2007,7(3):83-85
[22]詹宁育,王心如.辛硫磷与氰戊菊酯对大鼠睾丸的联合毒性作用[J].中华劳动卫生职业病杂志,2001,19(4):261-264.
[23]姚克文,王介东.氰戊菊酯对大鼠精子及生殖激素的影响[J].生殖医学杂志,2008,17(1):58-61.
[24]薛南冬,徐晓白,刘秀芬.北京官厅水库中农药类内分泌干扰物分布和来源[J].环境科学,2006,27(10):2081-2086.
[25]任晋,蒋可.阿特拉津及其降解产物对张家口地区饮用水资源的影响[J].科学通报,2002,47(10):748-762.
[26]丁振华,贾洪武,刘彩娥,等.黄浦江沉积物重金属的污染及评价[J].环境科学与技术,2006,29(2):64-66.
[27]李敏,宗栋良.地表水中重金属类环境激素污染调查术[J].广州化工,2010,38(8):217-223
[28]邵兵,胡建英,杨敏.重庆流域嘉陵江和长江水环境中壬基酚污染状况调查[J].环境科学学报,2002,22(1):12-16.
[29]段菁春,陈兵,麦碧娴,等.洪季珠江三角洲水系烷基酚污染状况研究[J].环境科学,2004,25(3):48-52
[30]沈钢,张祖麟,余刚,等.夏季海河与渤海湾中壬基酚和辛基酚污染的状况[J].中国环境科学,2005,25(6):733-736.
[31]黄长江,董巧香,雷瓒,等.我国东南沿海3港口有机锡污染的调查[J].海洋学报,2005,27(1):57-63.
[32]高俊敏,胡建英,金晓辉,等.水环境中的有机锡污染调查[J].中国给水排水,2004,20(7):25-27.
[33]Waring R H, Harris R M. Endocrine disrupters:A human risk?[J]. Molecular and Cellular Endocrinology,2005,244(1-2):2-9.
[34]Chantana P, Bill L, Lasley A, et al. Reproductive hormone hrofile along pesticide factory workers[J]. JOEM,1998,40(12):1038-1047.
[35]Wolff M S, Toniolo P G. Environmental organochlorine exposure as a potential etiologic factor in breast cancer[J]. Environmental Health Perspectives,1995, 103(Suppl7):141-145.
[36]Ginsburg J, Okolo S, Prelevic G, et al. Residence in the London area and sperm density[J]. Lancet,1994,343(8891):230-230.
[37]McLachlan J A, Simpson E, Martin M. Endocrine disrupters and female reproductive health[J]. Best Practice & Research Clinical Endocrinology & Metabolism,2006,20(1):63-75.
[38]Friedmann A S. Atrazine inhibition of testosterone production in rat males following peripubertal exposure[J]. Reproductive Toxicology,2002,16(3): 275-279.
[39]Graymore M, Stagnitti F, Allinson G. Impacts of atrazine in aquatic ecosystems[J]. Environment International,2001,26(7-8):483-495.
[40]Ansar Ahmed S. The immune system as a potential target for environmental estrogens (endocrine disrupters):a new emerging field[J]. Toxicology,2000, 150(1-3):191-206.
[41]余增丽,张立实,徐培渝,等.三种增塑剂对乳腺癌细胞株MCF-7增殖的影响[J].中华预防医学杂志,2003,37(3):150-153.
[42]Miodovnik A, Engel S M, Zhu C, et al. Endocrine disruptors and childhood social impairment[J]. Neurotoxicology,2011,32(2):261-267.
[43]Purdom C E H PA, Bye VJ, et al. Estrogenic effects of effluents from sewage treatments works[J]. Chem Ecol,1994, (8):275-285.
[44]Larsson D GJ A M, Parkkonen J, et al. Ethinyloestradiol-an undesired fishc ontraceptive[J]. Aquatic Toxicol,1999, (45):91-97.
[45]Jobling S S D, Osborne J A, et al. Inhibition of testicular growth in rainbow trout (Oncorhynchus mykiss) exposed to estrogenic alkylphenolic chemicals[J]. Environ T oxicol Chem,1996, (15):194-202.
[46]Navas M, Wenzel, et al. Linear alkylbenzene sulfonates and intermediate products from their degradation are not estrogenic[J]. Marine Pollution Bulletin,1999:38:880-884.
[47]Yokoata, Miyashita, Yuasa. High glucuronidation activity of environmental estrogens in the carp (Cyprinus carpino) intestine[J]. Life Sciences,2002, (71): 887-898.
[48]Pedersen, Hill. Tissue distribution and depuration of 4-tert-octylphenol residues in the cyprinid fish[[J]. Scardinius Erythrophthalmus, Environ. Sci Technol, 2002, (36):3275-3283.
[49]赵兵,刘征涛,徐章法,等.酚类化合物对金鱼幼鱼的雌激素效应研究[J].环境科学学报,2005,25(9):1259-1264.
[50]吕雪飞,周群芳,宋茂勇,等.17β-雌二醇、壬基酚及其混合物对雄性泥鳅的雌激素效应[J].科学通报,2007,52(18):2122-2126.
[51]夏继刚,牛翠娟.壬基酚暴露对斑马鱼求偶行为与繁殖成功率的影响[J].生态学报,2010,30(20):5537-5543.
[52]Thomas P. Effects of Aroclor 1254 and cadmium on reproductive endocrine function and ovarian growth in Atlantic croaker[J]. Marine Environmental Research,1989,28(1):499-503.
[53]Christiansen L B, Pedersen K L, Korsgaard B, et al. Estrogenicity of xenobiotics in rainbow trout (Oncorhynchus mykiss) using in vivo synthesis of vitellogenin as a biomarker[J]. Marine Environmental Research,1998, 46(1-5):137-140.
[54]刘德英,张剑波,丁剑.我国农药类环境内分泌干扰物使用现状和对策[J].环境保护,2005,(6):45-50.
[55]孟昭璐,刘皓慈,戎奕,等.阿特拉津对斑马鱼影响的研究[J].职业与健康,2008,24(003):205-208.
[56]陈家长,孟顺龙,胡庚东,等.阿特拉津对雄性鲫鱼血清雌二醇含量的影响[J].生态学杂志,2007,26(7):1068-1073.
[57]Drevnick P E, Sandheinrich M B. Effects of dietary methylmercury on reproductive endocrinology of fathead minnows[J]. Environmental science and technology,2003,37(19):4390-4396.
[58]米兆娟,李杰.三丁基氯化锡对哺乳动物生殖毒性及作用机制[J].中国公共卫生,2007,23(3):364-366.
[59]Gibbs P E, Pascoe P L, Burt G R. Sex Change in the Female Dog-Whelk, Nucella Lapillus, Induced by Tributyltin from Antifouling Paints[J]. Journal of the Marine Biological Association of the United Kingdom,1988,68(04): 715-731.
[60]Bryan G W, Gibbs P E, Burt G R, et al. The effects of tributyltin (TBT) accumulation on adult dog-whelks, Nucella lapillus:long-term field and laboratory experiments[J]. Journal of the Marine Biological Association of the United Kingdom,1987,67(03):525-544.
[61]Oehlmann J, Schulte-Oehlmann U, Tillmann M, et al. Effects of Endocrine Disruptors on Prosobranch Snails (Mollusca:Gastropoda) in the Laboratory. Part I:Bisphenol A and Octylphenol as Xeno-Estrogens[J]. Ecotoxicology, 2000,9(6):383-397.
[62]Morcillo Y, Porte C. Evidence of Endocrine Disruption in the Imposex-Affected Gastropod Bolinus brandaris[J]. Environmental Research, 1999,81(4):349-354.
[63]赵松涛,袁星,于书霞.环境激素对水蚤的影响[J].环境污染与防治,2001,23(6):314-316.
[64]Haeba M H, Hilscherova K, Mazurova E, et al. Selected endocrine disrupting compounds (vinclozolin, flutamide, ketoconazole and dicofol):Effects on survival, occurrence of males, growth, molting and reproduction of Daphnia magna[J]. Environmental Science and Pollution Research,2008,15(3): 222-227.
[65]Dodson S I, Merritt C M, Torrentera L, et al. Dieldrin reduces male production and sex ratio in Daphnia galeata mendotae[J]. Toxicology and Industrial Health,1999,15(1-2):192-199.
[66]Olmstead A W, Leblanc G A. Juvenoid hormone methyl farnesoate is a sex determinant in the crustacean Daphnia magna[J]. Journal of Experimental Zoology,2002,293(7):736-739.
[67]Brown R J, Conradi M, Depledge M H. Long-term exposure to 4-nonylphenol affects sexual differentiation and growth of the amphipod Corophium volutator (Pallas,1766) [J]. Sci.Total Environ,1999, (233):77-88.
[68]Hutchinson T H, Pounds N A, Hampel M, et al. Life-cycle effects of 20-hydroxyecdysone and di-ethylstilbestrol on the marine copepod Tisbe battagliai[J]. Environ. Toxicol. Chem,1999, (18):2914-2920.
[69]Hutchinson T H, Pounds N A, Hampel M, et al. Impact of ecdysteroids and oestrogens on develop-mental and reproductive parameters in the marine copepod.Tisbe battagliai[J]. Sci.Total Environ,1999, (233):167-179.
[70]Andersen H R, L., Wollenberger B H, O.Kusk K. Development of copepod nauplii to copepodites:a parameter for chronic toxicity including endocrine disruption[J]. Environ.Toxicol.Chem,2001, (20):2821-2829.
[71]Breitholtz M, Bengtsson B E. Oestrogens have no hormonal effect on the development and reproduction of the harpacticoid copepod Nitocra spi nipes[J]. Mar.Pollut.Bul,2001,1(42):879-886.
[72]Gross M Y, Maycock D S, Thorndyke M C, et al. Abnormalities in sexual development of the amphipod Gammarus pulex (L.) found below sewage treatment works[J]. Environ. Toxicol. Chem,2001, (20):1792-1797.
[73]Billinghurst Z, Clare A S, T F. Inhibition of barnacle settlement by the environmental oestrogen 4-nonylphenol and the natural oestrogen 17 beta oestradio[J]. Mar Pollut Bull,1998,36(10):833-839.
[74]Billinghurst Z, Clare A S, Matsumura K, et al. Induction of cypris major protein in barnacle larvae by exposure to 4-n-nonylphenol and 17p-oestradiol[J]. Aquatic Toxicology,2000,47(3-4):203-212.
[75]Atienzar F A, Billinghurst Z, Depledge M H.4-n-Nonylphenol and 17-β estradiol may induce common DNA effects in developing barnacle larvae[J]. Environmental Pollution,2002,120(3):735-738.
[76]蔡立哲,厉红梅,邹朝中.深圳河口福田泥滩海洋线虫的种类组成及季节变化[J].生物多样性,2000,8(4):385-390.
[77]王硕治,汝少国,杜恩在.化学物质对自由生活线虫毒性效应生物标志物研究进展[J].科技导报,2007,18(18):75-80.
[78]Tominaga N, Kunimoto M, Kai T, et al. A Convenient Assay for Evaluating Chemical Toxicity Using Caenorhabditis elegans as a Model Organism-Application to Alkylphenol Toxicity Test-[J]. Environ Sci,2003, 10(4):215-221.
[79]Kohra S, Tominaga N, Mitsui Y, et al. Determination of a screening system of endocrine disruptors by the induction of vitellogenin mRNA in C. elegans larvae[J]. Japanese Journal of Toxicology & Environmental Health,1999,45.
[80]王摆,汝少国,王蔚.久效磷对细小色矛线虫胚胎发育和繁殖的影响[J].中国环境科学,2009,29(5):543-547.
[81]田雨,汝少国.久效磷对秀丽隐杆线虫(Caenorhabditis elegans)胁迫相关基因mRNA表达的影响[J].中国海洋大学学报,2012.42(3):35-42.
[82]Starkweather P L. Rotifera,in animal energetics.Vol.1.Protozoa through insecta,Pandian TJ and Verberg FJ(Eds)[J]. Academic Press,Orlando, FL, 1987.
[83]Wallace RL S T. Rotifera,in Thorp JH,Covich AP.(eds.).Ecology and systematics of North Americal freshwater invertebrates[J]. Acedamic presss,New York,,1991:187-248.
[84]Gilbert J J. Timing of diapause in monogonont rotifers:Machanisms and strategies.In:Alekseev VR, De Stasio B, Gilbert JJ, editor. Diapause in Aquatic Invertebrates:Theory and Human use.Dordrecht:Springer pp. 11-27[J].2007.
[85]Birky C W, Gilbert J J. Parthenogenesis in rotifers:The control of sexual and asexual reproduction [J]. Am. Zool,1971, (11):245-246.
[86]Pourriot R, Snell T W. Resting eggs in rotifers[J]. Hydrobiologia,1983,104(1): 213-224.
[87]Gilbert J J. Environmental and endogenous control of sexuality in a rotifer life cycle:developmental and population biology[J]. Evolution & Development, 2003,5(1):19-24.
[88]Snell T W, Kubanek J, Carter W, et al. A protein signal triggers sexual reproduction in Brachionus plicatilis (Rotifera)[J]. Marine Biology,2006, 149(4):763-773.
[89]Snell T. Sex, population dynamics and resting egg production in rotifers[J]. Hydrobiologia,1987,144(2):105-111.
[90]Azuara-Garcia R, Sarma S S S, Nandini S. The combined effects of zinc and alga on the life table demography of Anuraeopsis fissa and Brachionus rublens (Rotifera)[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances & Environmental Engineering,2006,41(4): 559-572.
[91]Snell T W, Moffat B D. A 2-d Life cycle test with the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1992,11(9): 1249-1257.
[92]Snell T W, Janssen C R. Rotifers in ecotoxicology:A review[J]. Hydrobiologia, 1995,313-314(0):231-247.
[93]Schaefer E D, Pipes W O. Temperature and the toxicity of chromate and arsenate to the rotifer philodina roseola.[J]. Water Res.,1973, (7):1781-1790.
[94]Snell T W, Persoone G. Acute toxicity bioassays using rotifers. Ⅱ. A freshwater test with Brachionus rubens[J]. Aquatic Toxicology,1989,14(1):81-91.
[95]Charoy C, Janssen C R. The swimming behaviour of Brachionus calyciflorus (rotifer) under toxic stress. II. Comparative sensitivity of various behavioural criteria[J]. Chemosphere,1999,38(14):3247-3260.
[96]Ramirez-Perez T, Sarma S S S, Nandini S. Effects of mercury on the life table demography of the rotifer Brachionus calyciflorus pal las (rotifera)[JJ. Ecotoxicology,2004,13(6):535-544.
[97]Snell T W, Joaquim-Justo C. Workshop on rotifers in ecotoxicology[J]. Hydrobiologia,2007,593:227-232.
[98]Snell T W, Carmona M J. Surface glycoproteins in copepods:Potential signals for mate recognition[J]. Hydrobiologia,1994,292-293(0):255-264.
[99]Snell T W. Chemical ecology of rotifers[J]. Hydrobiologia,1998,387-388(0): 267-276.
[100]Snell T W, Shearer T L, Smith H A, et al. Genetic determinants of mate recognition in Brachionus manjavacas (Rotifera)[J]. Bmc Biology,2009,7.
[101]金解敏,杨家新,陈立侨.铜锌离子对褶皱臂尾轮虫的急性毒性试验[J]. 水产科技情报,1999,26(3):121-123.
[102]Xi Y L, Hu H Y. Effect of thiophanate-methyl on the reproduction and survival of the freshwater rotifer Brachionus calyciflorus pallas[J]. Bulletin of Environmental Contamination and Toxicology,2003,71(4):722-728.
[103]Halbach U. Population dynamics of rotifers and its consequences for ecotoxicology[J]. Hydrobiologia,1984,109(1):79-96.
[104]Halbach U, Siebert M, Westermayer M, et al. Population ecology of rotifers as a bioassay tool for ecotoxicological tests in aquatic environments[J]. Ecotoxicology and environmental safety,1983,7(5):484-513.
[105]Snell T W, Persoone G. Acute toxicity bioassays using rotifers. I. A test for brackish and marine environments with Brachionus plicatilis[J]. Aquatic Toxicology,1989,14(1):65-80.
[106]Snell T W, Moffat B D, Janssen C, et al. Acute toxicity tests using rotifers. IV. Effects of cyst age, temperature, and salinity on the sensitivity of Brachionus calyciflorus[J]. Ecotoxicology and Environmental Safety,1991,21(3): 308-317.
[107]Ferrando M D, Andreu-Moliner E. Acute lethal toxicity of some pesticides to Brachionus calyciflorus and Brachionus plicatilis[J]. Bulletin of Environmental Contamination and Toxicology,1991,47(3):479-484.
[108]Fernandez-Casalderry A, Ferrando M D, Andreu-Moliner E. Acute toxicity of several pesticides to rotifer (Brachionus calyciflorus)[J]. Bulletin of Environmental Contamination and Toxicology,1992,48(1):14-17.
[109]Snell T W, Childress M J, Boyer E M, et al. Assessing the status of rotifer mass cultures[J]. J.World Aquacult.Soc,,1987, (18):270-277.
[110]Janssen C R, Ferrando M D, Persoone G. Ecotoxicological Studies with the Freshwater Rotifer Brachionus calyciflorus:Ⅳ. Rotifer Behavior as a Sensitive and Rapid Sublethal Test Criterion[J]. Ecotoxicology and Environmental Safety,1994,28(3):244-255.
[111]Janssen C R, Ferrando M D, Persoone G. Ecotoxicological Studies with the Freshwater Rotifer Brachionus calyciflorus:Ⅰ.Conceptual framework and applications[J]. Hydrobiologia,1993, (255/256):21-32.
[112]Beauvais J E, Enesco H E. Life span and age-related changes in activity level of the rotifer Asplanchna brightwelli:influence of curare[J]. Experimental gerontology,1985,20(6):359-366.
[113]Charoy C P, Janssen C R, Persoone Q et al. The swimming behaviour of Brachionus calyciflorus (rotifer) under toxic stress. I. The use of automated trajectometry for determining sublethal effects of chemicals[J]. Aquatic Toxicology,1995,32(4):271-282.
[114]Snell T W. Rotifer Ingestion Test for Rapid Assessment of Toxicity. In:Blaise C, Ferard J-F, eds. Small-scale Freshwater Toxicity Investigations:Springer Netherlands; 2005:323-335.
[115]Starkweather P L, Gilbert J J. Feeding in the rotifer Brachionus calyciflorus[J]. Oecologia,1977,28(2):133-139.
[116]Schlosser H, Anger K. The significance of some methodological effects on filtration and ingestion rates of the rotife Brachionus plicatilis[J]. Helgoland Marine Research,1982,35(2):215-225.
[117]Starkweather P L, Gilbert J J, Frost T M. Bacterial feeding by the rotifer Brachionus calyciflorus clearance and ingestion rates, behavior and population dynamics[J]. Oecologia,1979,44(1):26-30.
[118]Juchelka C M, Snell T W. Rapid toxicity assessment using rotifer ingestion rate[J]. Archives of Environmental Contamination and Toxicology,1994, 26(4):549-554.
[119]Juchelka C M, Snell T W. Rapid toxicity assessment using ingestion rate of cladocerans and ciliates[J]. Archives of Environmental Contamination and Toxicology,1995,28(4):508-512.
[120]徐晓平,席贻龙,储昭霞,等.溴氰菊酯对萼花臂尾轮虫实验种群动态的影响[J].动物学报,2005,51(2):251-256.
[121]储昭霞,席贻龙,徐晓平,等.除草剂草甘膦对萼花臂尾轮虫生活史特征的影响[J].应用生态学报,2005,16(6):1142-1145.
[122]Huang L, Xi Y L, Zha C W, et al. Effect of aldrin on life history characteristics of rotifer Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2007,79(5):524-528.
[123]Marcial H S, Hagiwara A. Effect of diazinon on life stages and resting egg hatchability of rotifer Brachionus plicatilis[J]. Hydrobiologia,2007,593: 219-225.
[124]Ferrando M D, Janssen C R, Andreu E, et al. Ecotoxicological studies with the freshwater rotifer Brachionus calyciflorus II. An assessment of the chronic toxicity of lindane and 3,4-dichloroaniline using life tables[J]. Hydrobiologia, 1993,255-256(1):33-40.
[125]Ramakrishna Rao T, Sarma S S S. Demographic parameters of Brachionus patulus Muller (Rotifera) exposed to sublethal DDT concentrations at low and high food levels[J]. Hydrobiologia,1986,139(3):193-200.
[126]Fernandez-Casalderrey A, Ferrando M D, Andreu-Moliner E. Demographic parameters of Brachionus calyciflorus Pallas (Rotifers) exposed to sublethal endosulfan concentrations[J]. Hydrobiologia,1991,226(2):103-110.
[127]Zha C W, Xi Y L, Huang L, et al. Effect of sublethal exposure to chlordecone on life history characteristics of freshwater rotifer Brachionus calyciflorus pallas[J]. Bulletin of Environmental Contamination and Toxicology,2007, 78(1):71-75.
[128]Sarma S S S, Nandini S, Flores J L G. Effect of methyl parathion on the population growth of the rotifer Brachionus patulus (O. F. Muller) under different algal food (Chlorella vulgaris) densities[J]. Ecotoxicology and Environmental Safety,2001,48(2):190-195.
[129]Belgis C, Guido P. Cyst-based toxicity tests. XI. Influence of the type of food on the intrinsic growth rate of the rotifer Brachionus calyciflorus in short-chronic toxicity tests[J]. Chemosphere,2003,50(3):365-372.
[130]Belgis C, Persoone G Cyst-based toxicity tests XVII-Prefeeding advantages in short-chronic rotifer microbiotests[J]. Ecotoxicology and Environmental Safety,2005,60(1):73-80.
[131]Janssen C R, Persoone G, Snell T W. Cyst-base toxicity tests:VIII. Short-chronic toxicity tests with the freshwater rotifer Brachionus calyciflorus[J]. Aquatic Toxicology (Amsterdam),1994,28(3-4):243-258.
[132]Preston B L, Snell T W, Robertson T L, et al. Use of freshwater rotifer Brachionus calyciflorus in screening assay for potential endocrine disruptors[J]. Environmental Toxicology and Chemistry,2000,19(12): 2923-2928.
[133]Radix P, Severin Q Schramm K W, et al. Reproduction disturbances of Brachionus calyciflorus (rotifer) for the screening of environmental endocrine disrupters[J]. Chemosphere,2002,47(10):1097-1101.
[134]Sarma S S S, Ramiez-Perez T, Nandini S, et al. Combined Effects of Food Concentration and the Herbicide 2,4-Dichlorophenoxyacetic Acid on the Population Dynamics of Brachionus patulus (Rotifera)[J]. Ecotoxicology, 2001,10(2):91-99.
[135]Gama Flores J L, Sarma S S S, Fernandez Araiza M A. Combined Effects of Chlorella;Density and Methyl Parathion Concentration on the Population Growth of Brachionus calyciflorus(Rotifera)[J]. Bulletin of Environmental Contamination and Toxicology,1999,62(6):769-775.
[136]Preston B L, Snell T W. Full life-cycle toxicity assessment using rotifer resting egg production:implications for ecological risk assessment[J]. Environmental Pollution,2001,114(3):399-406.
[137]Snell T W, Janssen C R. Comparative toxicant sensitivity of sexual and asexual reproduction in the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1995,14(3):415-420.
[138]Marcial H, Hagiwara A, Snell T. Effect of some pesticides on reproduction of rotifer Brachionus plicatilis Miiller. In:Herzig A, Gulati R, Jersabek C et al., eds. Rotifera X:Springer Netherlands; 2005:569-575.
[139]Snell T W, Carmona M J. Comparative toxicant sensitivity of sexual and asexual reproduction in the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1995,14(3):415-420.
[140]Gallardo W G, Hagiwara A, Tomita Y, et al. Effect of some vertebrate and invertebrate hormones on the population growth, mictic female production, and body size of the marine rotifer Brachionus plicatilis Muller[J]. Hydrobiologia,1997,358(0):113-120.
[141]Xi Y L, Feng L K. Effects of Thiophanate-Methyl and Glyphosate on Asexual and Sexual Reproduction in the Rotifer Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2004,73(4): 644-651.
[142]Marcial H S, Hagiwara A, Snell T W. Effect of some pesticides on reproduction of rotifer Brachionus plicatilis Muller[J]. Hydrobiologia,2005, 546:569-575.
[143]Snell T W, DesRosiers N J D. Effect of progesterone on sexual reproduction of Brachionus manjavacas (Rotifera)[J]. Journal of Experimental Marine Biology and Ecology,2008,363(1-2):104-109.
[144]Sarma S S S, Brena-Bustamante P, Nandini S. Body size and population growth of Brachionus patulus (Rotifera) in relation to heavy metal (copper and mercury) concentrations[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances & Environmental Engineering,2008, 43(5):547-553.
[145]Sarma S S S, Gulati R D, Nandini S. Factors affecting egg-ratio in planktonic rotifers[J]. Hydrobiologia,2005,546:361-373.
[146]Moffat B D, Snell T W. Rapid toxicity assessment using an in vivo enzyme test for Brachionus plicatilis (Rotifera)[J]. Ecotoxicology and Environmental Safety,1995,30(1):47-53.
[147]Burbank S E, Snell T W. Rapid toxicity assessment using esterase biomarkers in Brachionus calyciflorus (Rotifera)[J]. Environmental Toxicology and Water Quality,1994,9(3):171-178.
[148]Rios-Arana J V, Gardea-Torresdey J L, Webb R, et al. Heat shock protein 60 (HSP60) response of Plationus patulus (Rotifera:Monogononta) to combined exposures of arsenic and heavy metals[J]. Hydrobiologia,2005,546:577-585.
[149]Kim R-O, Rhee J-S, Won E-J, et al. Ultraviolet B retards growth, induces oxidative stress, and modulates DNA repair-related gene and heat shock protein gene expression in the monogonont rotifer, Brachionus sp[J]. Aquatic Toxicology,2011,101(3-4):529-539.
[150]Smith H A, Burns A R, Shearer T L, et al. Three heat shock proteins are essential for rotifer thermotolerance[J]. Journal of Experimental Marine Biology and Ecology,2012,413:1-6.
[151]Cochrane B J, Irby R B, Snell T W. Effects of copper and tributyltin on stress protein abundance in the rotifer Brachionus plicatilis[J]. Comparative Biochemistry and Physiology Part C:Comparative Pharmacology,1991, 98(2-3):385-390.
[152]Wheelock C E, Wolfe M F, Olsen H, et al. Hsp60-induced tolerance in the rotifer Brachionus plicatilis exposed to multiple environmental contaminants[J]. Archives of Environmental Contamination and Toxicology, 1999,36(3):281-287.
[153]Wheelock C E, Baumgartner T A, Newman J W, et al. Effect of nutritional state on Hsp60 levels in the rotifer Brachionus plicatilis following toxicant exposure[J]. Aquatic Toxicology,2002,61(1-2):89-93.
[154]Snell T, Joaquim-Justo C. Workshop on rotifers in ecotoxicology[J]. Hydrobiologia,2007,593(1):227-232.
[155]Dahms H-U, Hagiwara A, Lee J-S. Ecotoxicology, ecophysiology, and mechanistic studies with rotifers[J]. Aquatic Toxicology,2011,101(1):1-12.
[156]ASTM. Standard guide for acute toxicity tests with the rotifer Brachionus. Annual Book of ASTM Standards vol.11.04, E1440.Philadelphia,PA,USA:American Society for Testing and Material.[J]. 1991.
[157]Gallardo W G, Hagiwara A, Tomita Y, et al. Effect of some vertebrate and invertebrate hormones on the population growth, mictic female production, and body size of the marine rotifer Brachionus plicatilis Muller[S]. Hydrobiologia,1997,358(1):113-120.
[158]Zhu W G G R X, Yang J X. Effect of endocrine disruptors fenvalerate and TBTC on reproduction of rotifer Brachionus calyciflorus[J]. Acta Ecologica Sinica,2009,29(7):3605-3612.
[159]Yang J, Snell T W. Effects of Progesterone, Testosterone, and Estrogen on Sexual Reproduction of the Rotifer Brachionus calyciflorus[J]. International Review of Hydrobiology,2010,95(6):441-449.
[160]张琴,包丽颖,刘伟江,等.我国饮用水水源内分泌干扰物的污染现状分析[J].环境科学与技术,2011,34(2):91-96.
[161]覃丹丹,袁伟,高尔生.双酚A对雄性生殖功能影响的研究进展[J].环境与健康杂志,2008,24(7):550-552.
[162]Izumi N, Yanagibori R, Shigeno S, et al. Effects of bisphenol A on the development, growth, and sex ratio of the housefly Musca domestica[J]. Environmental Toxicology and Chemistry,2008,27(6):1343-1353.
[163]Lemos M F L, van Gestel C A M, Soares A M V M. Endocrine disruption in a terrestrial isopod under exposure to bisphenol A and vinclozolin[J]. Journal of Soils and Sediments,2009,9(5):492-500.
[164]Anonymous. Methods of measuring the acute toxicity of effluents to freshwater and marine organisms. [J]. Environ-ment Protection Agency EPA/600/4-85/013.,1985.
[165]Zhang Z.S, X.F. H. Method for Study on Freshwater Plankton.Beijing:Science Press.410-411(in Chinese).[J].1991.
[166]Finley D J. Probit analysis.3rd ed[J]. Cambridge Univ. Press, London,1971.
[167]Walz N. Individual culture and experimental population dynamics of Keratella cochlearis (Rotatoria)[J]. Hydrobiologia,1983,107(1):35-45.
[168]Korstad J, Olsen Y, Vadstein O. Life history characteristics of Brachionus plicatilis (rotifera) fed different algae[J]. Hydrobiologia,1989,186-187(1): 43-50.
[169]Schmid-Araya J M. The effect of food concentration on the life histories of Brachionus plicatilis (O. F. M.) and Encentrum linnhei Scott[J]. Archiv fur Hydrobiologie,1991,121(1):87-102.
[170]Krebs C J. Ecology. The Experimental Analysis of Distribution and Abundance. Harper and Row, New York.[J].1985.
[171]刘红玲,刘晓华,王晓祎,等.双酚A和四溴双酚A对大型溞和斑马鱼的毒性[J].环境科学,2007,(8):184-1787
[172]郭匿春,谢平.双酚A和壬基酚对隆线溞和微型裸腹溞的毒性[J].水生生物学报,2009,(3):492-497
[173]孙小娜,李晓彩,马爱团,等.双酚A对雄性小鼠睾丸发育和生殖激素分泌水平的影响[J].中国兽医科学,2010,40(009):949-952.
[174]黄晔,任华,孙竹筠,等.壬基酚和双酚A对雄性斑马鱼(Danio rerio)卵黄蛋白原mRNA的诱导效应[J].生态毒理学报,2008,3(3):274-279.
[175]雷忻,李宗强,廉振民,等.双酚A和对硝基酚对泥鳅的急性毒性效应[J].生态学杂志,2009,28(11):2257-2261.
[176]端正花,朱琳,王平,等.双酚A对斑马鱼不同发育阶段的毒性及机理[J].环境化学,2007,(4):491-494
[177]Galkovskaja G Planktonic rotifers and temperature[J]. Hydrobiologia,1987, 147(1):307-317.
[178]Awaiss A, Kestemont P. An investigation into the mass production of the freshwater rotifer Brachionus calyciflorus Pallas.2. Influence of temperature on the population dynamics[J]. Aquaculture,1992,105(3):337-344.
[179]Yoshinaga T, Hagiwara A, Tsukamoto K. Effect of conditioned media on the asexual reproduction of the monogonont rotifer Brachionus plicatilis O.F. Muller[J]. Hydrobiologia,1999, (412):103-110.
[180]Pourriot R. Les rotiferes biologie. [J]. Aquaculture,1986,5:201-221.
[181]Janssen C R, Ferrando Rodrigo M D, Persoone G Ecotoxicological studies with the freshwater rotifer, Brachionus calyciflorus[J]. Hydrobiologia,1993, 255-256(1):21-32.
[182]Huang L, Xi Y L, Zha C W, et al. Effect of Aldrin on Life History Characteristics of Rotifer, Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2007,79(5):524-528.
[183]Ramakrishna Rao T, Sarma S. Demographic parameters of Brachionus patulus Muller (Rotifera) exposed to sublethal DDT concentrations at low and high food levels[J]. Hydrobiologia,1986,139(3):193-200.
[184]Huang Y Q, Wong C K C, Zheng J S, et al. Bisphenol A (BPA) in China:A review of sources, environmental levels, and potential human health impacts[J]. Environment International,2012,42(0):91-99.
[185]Fukuhori N, Kitano M, Kimura H. Toxic Effects of Bisphenol A on Sexual and Asexual Reproduction in Hydra oligactis[J]. Archives of Environmental Contamination and Toxicology,2005,48(4):495-500.
[186]Kwak H-I, Bae M-O, Lee M-H, et al. Effects of nonylphenol, bisphenol a, and their mixture on the viviparous swordtail fish (Xiphophorus helleri)[J]. Environmental Toxicology and Chemistry,2001,20(4):787-795.
[187]Gallardo W G, Hagiwara A, Snell T W. Effect of juvenile hormone and serotonin (5-HT) on mixis induction of the rotifer Brachionus plicatilis Muller[J]. Journal of Experimental Marine Biology and Ecology,2000,252(1): 97-107.
[188]Fernandez-Casalderrey A, Ferrando M, Andreu-Moliner E. Demographic parameters of Brachionus calyciflorus Pallas (Rotifers) exposed to sublethal endosulfan concentrations[J]. Hydrobiologia,1991,226(2):103-110.
[189]Fernandez-Casalderry A, Ferrando M D, Andreu-Moliner E. Acute toxicity of several pesticides to rotifer(Brachionus calyciflorus)[S]. Bulletin of Environmental Contamination and Toxicology,1992,48(1):14-17.
[190]Sohoni P, Tyler C, Hurd K, et al. Reproductive effects of long-term exposure to bisphenol A in the fathead minnow (Pimephales promelas)[J]. Environmental science & technology,2001,35(14):2917-2925.
[191]Kang J-H, Aasi D, Katayama Y. Bisphenol A in the aquatic environment and its endocrine-disruptive effects on aquatic organisms[J]. CRC Critical Reviews in Toxicology,2007,37(7):607-625.
[192]黄晔,任华,孙竹筠,等.壬基酚和双酚A对雄性斑马鱼(Danio rerio)卵黄蛋白原mRNA的诱导效应[J].生态毒理学报,2008,3(3):274-279.
[193]Snell T W, Moffat B D. A 2-d Life cycle test with the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1992,11(9): 1249-1257.
[194]Xi Y L, Feng L K. Effects of thiophanate-methyl and glyphosate on asexual and sexual reproduction in the rotifer Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2004,73(4): 644-651.
[195]Ke L-X, Xi Y-L, Zha C-W, et al. Effects of three organophosphorus pesticides on population growth and sexual reproduction of rotifer Brachionus calyciflorus Pallas[J]. Acta Ecologica Sinica,2009,29(3):182-185.
[196]乔坤,刘媛媛,李玉华,等.双酚A斑马鱼雄性生殖毒性的表观遗传学基础[J].实验动物与比较医学,2012,32(1):30-37.
[197]Siebers J, Gottschild D, Nolting H-G. Pesticides in precipitation in northern Germany[J]. Chemosphere,1994,28(8):1559-1570.
[198]Donna A, Betta P-G, Robutti F, et al. Ovarian mesothelial tumors and herbicides:a case-control study[J]. Carcinogenesis,1984,5(7):941-942.
[199]Cooman K, Debels P, Gajardo M, et al. Use of Daphnia spp. for the ecotoxicological assessment of water quality in an agricultural watershed in south-central Chile[J]. Archives of Environmental Contamination and Toxicology,2005,48(2):191-200.
[200]Hayes T B, Khoury V, Narayan A, et al. Atrazine induces complete feminization and chemical castration in male African clawed frogs (Xenopus laevis)[J]. Proceedings of the National Academy of Sciences of the United States of America,2010,107(10):4612-4617.
[201]Tillitt D E, Papoulias D M, Whyte J J, et al. Atrazine reduces reproduction in fathead minnow (Pimephales promelas)[J]. Aquatic Toxicology,2010,99(2): 149-159.
[202]Marcial H S, Hagiwara A. Effect of diazinon on life stages and resting egg hatchability of rotifer Brachionus plicatilis[J]. Hydrobiologia,2007,593(1): 219-225.
[203]Xi Y L, Huang X F, Jin H J. Life history characteristics of three types of females in Brachionus calyciflorus Pallas (Rotifera) fed different algae[J]. Hydrobiologia,2001,446:95-98.
[204]Fernandez-Casalderrey A, Ferrando M, Andreu-Moliner E. Effect of sublethal diazinon concentrations on the demographic parameters of Brachionus calyciflorus Pallas (Rotifera)[J]. Bulletin of Environmental Contamination and Toxicology,1992,48(2):202-208.
[205]Fernandez-Casalderrey A, Ferrando M D, Andreu-Moliner E. Endosulfan and diazinon toxicity to the freshwater rotifer Brachionus calyciflorus[J].Journal of environmental science and health. Part. B, Pesticides, food contaminants, and agricultural wastes,1992,27(2):155-164.
[206]Giddings J M, Biever R C, Annuziato M E, et al. Effects of diazinon on large outdoor pond microcosms[J]. Environmental Toxicology and Chemistry,1996, 15(5):618-629.
[207]Gentile J H, Gentile S M, Hairston N G, et al. The use of life-tables for evaluating the chronic toxicity of pollutants to Mysidopsis bahia [J]. Hydrobiologia,1982,93(1):179-187.
[208]Day K, Kaushik N K. An assessment of the chronic toxicity of the synthetic pyrethroid, fenvalerate, to Daphnia galeata mendotae, using life tables[J]. Environmental Pollution,1987,44(1):13-26.
[209]Janssen C, Persoone G, Snell T. Cyst-based toxicity tests. Ⅷ. Short-chronic toxicity tests with the freshwater rotifer Brachionus calyciflorus[J]. Aquatic Toxicology,1994,28(3):243-258.
[210]Sanchez M, Ferrando M D, Sancho E, et al. Assessment of the toxicity of a pesticide with a two-generation reproduction test using Daphnia magna[J]. Comparative Biochemistry and Physiology Part C:Pharmacology, Toxicology and Endocrinology,1999,124(3):247-252.
[211]Palma P, Palma V, Matos C, et al. Effects of atrazine and endosulfan sulphate on the ecdysteroid system of Daphnia magna[J]. Chemosphere,2009,74(5): 676-681.
[212]Vandenbergh G F, Adriaens D, Verslycke T, et al. Effects of 17a-ethinylestradiol on sexual development of the amphipod Hyalella azteca[J]. Ecotoxicol. Environ. Saf.,2003,54(216-222).
[213]Cleuvers M, Goser B, Ratte H-T. Life-strategy shift by intraspecific interaction in Daphnia magna:change in reproduction from quantity to quality[J]. Oecologia,1997,110(3):337-345.
[214]叶伟红,刘维屏,谭亚军.氟氯菊酯对大型蚤的亚慢性毒性及其恢复实验[J].农药,2004,43(2):86-89.
[215]Zou E, Bu S. Acute toxicity of copper, cadmium, and zinc to the water flea, Moina irrasa (Cladocera)[J]. Bulletin of Environmental Contamination and Toxicology,1994,52(5):742-748.
[216]Hayashi Y, Heckmann L-H, Callaghan A, et al. Reproduction recovery of the crustacean Daphnia magna after chronic exposure to ibuprofen[J]. Ecotoxicology,2008,17(4):246-251.
[217]乔广浩,刘欣.杀虫剂西维因毒性及雌激素活性进展研究[J].环境科学与技术,2010,33(002):99-105.
[218]Boran M, Altinok I, Capkin E, et al. Acute toxicity of carbaryl, methiocarb, and carbosulfan to the rainbow trout (Oncorhynchus mykiss) and guppy (Poecilia reticulata)[J]. Turkish Journal of Veterinary & Animal Sciences, 2007,31(1):39-45.
[219]Todd N E, Van Leeuwen M. Effects of Sevin (carbaryl insecticide) on early life stages of zebrafish (Danio rerio)[J]. Ecotoxicology and Environmental Safety,2002,53(2):267-272.
[220]Tripathi P K, Singh A. Carbaryl induced alterations in the reproduction and metabolism of freshwater snail Lymnaea acuminata[J]. Pesticide Biochemistry and Physiology,2004,79(1):1-9.
[221]Tripathi P K, Singh A. Toxic effects of dimethoate and carbaryl pesticides on reproduction and related enzymes of the freshwater snail Lymnaea acuminata[J]. Bulletin of Environmental Contamination and Toxicology,2003, 71(3):535-542.
[222]李燕南,谈立峰,孙雪照,等.职业暴露甲萘威对女性生殖内分泌的影响[J].中国工业医学杂志,2005,18(3):163-165.
[223]Hanazato T. Effects of long-and short-term exposure to carbaryl on survival, growth and reproduction of Daphnia ambigua[J]. Environmental Pollution, 1991,74(2):139-148.
[224]Cerbin S, Kraak M H S, de Voogt P, et al. Combined and single effects of pesticide carbaryl and toxic Microcystis aeruginosa on the life history of Daphnia pulicaria[J]. Hydrobiologia,2010,643:129-138.
[225]Sakamoto M, Chang K H, Hanazato T. Differential sensitivity of a predacious cladoceran (Leptodora) and its prey (the cladoceran Bosmina) to the insecticide carbaryl:Results of acute toxicity tests[J]. Bulletin of Environmental Contamination and Toxicology,2005,75(1):28-33.
[226]Hanazato T, Yasuno M. Effects of a carbamate insecticide, carbaryl, on the summer phyto-and zooplankton communities in ponds[J]. Environmental Pollution,1987,48(2):145-159.
[227]Xi Y L, Huang X F, Jin H J, et al. The effect of food concentration on the life history of three types of Brachionus calyciflorus females[J]. International Review of Hydrobiology,2001,86(2):211-217.
[228]Moore A, Waring C. Sublethal effects of the pesticide Diazinon on olfactory function in mature male Atlantic salmon parr[J]. Journal of Fish Biology,1996, 48(4):758-775.
[229]Hanazato T. Pesticide effects on structure of zooplankton community and functioning of lake ecosystem[J]. Acta Hydrobiologica Sinica,1997, 21(SUPPL.):22-28.
[230]Lionetto M G, Caricato R, Erroi E, et al. Carbonic anhydrase-based environmental bioassay[J]. International Journal of Environmental Analytical Chemistry,2005,85(12-13):895-903.
[231]Bielza P, Fernandez E, Gravalos C, et al. Carbamates Synergize the Toxicity of Acrinathrin in Resistant Western Flower Thrips (Thysanoptera: Thripidae)[J]. Journal of Economic Entomology,2009,102(1):393-397.
[232]Snell T W, Janssen C R. Rotifers in ecotoxicology:a review[J]. Hydrobiologia, 1995,313-314(1):231-247.
[233]A.Ferna ndez-Casalderry, M.D.Ferrando a E, Andreu-Moliner. Acute Toxicity of Several Pesticides to Rotifer(Brachionus calyciflorus) [J]. Bull. Environ. Contain. Toxicol,1992, (48):14-17.
[234]Sarma S S S, Jurado P S L, Nandini S. Effect of three food types on the population growth of Brachionus calyciflorus and Brachionus patulus (Rotifera:Brachionidae)[J]. Revista De Biologia Tropical,2001,49(1):77-84.
[235]Gilbert J J. Effect of food concentration on the production and viability of resting eggs of the rotifer Brachionus:implications for the timing of sexual reproduction[J]. Freshwater Biology,2010,55(12):2437-2446.
[236]Hagiwara A, Hino A. Effect of incubation and preservation on resting egg hatching and mixis in the derived clones of the rotifer Brachionus plicatilis[J]. Hydrobiologia,1989,186-187(1):415-421.
[237]Hagiwara A, Hino A, Hirano R. Effect of temperature and chlorinity on resting egg formation in the rotifer Brachionus plicatilis[J]. Nippon Suisan Gakkaishi,1988, (54):569-575.
[238]Lindley J A, P.Donkin, S.V.Evans, et al. Effects of two organochlorine compounds on hatching and viability of calanoid copepod eggs[J]. Journal of Experimental Marine Biology and Ecology,1999,242:59-74.
[239]Snell T W, M.Serra, M.J.Carmona. Toxicity and sexual reproduction in rotifers:Reduced resting egg production and heterozygosity loss In Forbes,V.E.(ed)[J]. Genetics and Ecotoxicology,1999, (Taylor and Francis): 169-185.
[240]Snell T W, Serra M. Using probability of extinction to evaluate the ecological significance of toxicant effects[J]. Environmental Toxicology and Chemistry, 2000,19(9):2357-2363.
[241]邴欣,汝少国,姜明.久效磷对金鱼的环境雌激素效应的研究[J].高技术通讯,2007,16(11):1195-1199.
[242]Wang L, Ye W, Zhou S, et al. Acute and chronic toxicity of organophosphate monocrotophos to Daphnia magna[J]. Journal of Environmental Science and Health, Part B,2009,44(1):38-43.
[243]Rao J V, Gunda V, Srikanth K, et al. Acute toxicity bioassay using Paramecium caudatum, a key member to study the effects of monocrotophos on swimming behaviour, morphology and reproduction[J]. Toxicological and Environmental Chemistry,2007,89(2):307-317.
[244]Joshi U M, Desai A K. Biochemical changes in the liver of fish, Tilapia mossambica (Peters), during continuous exposure to monocrotophos[J]. Ecotoxicology and Environmental Safety,1988,15(3):272-276.
[245]Gallardo W G, Hagiwara A, Snell T W. GABA enhances reproduction of the rotifer Brachionus plicatilis Muller:application to mass culture[J]. Aquaculture Research,2000,31(8-9):713-718.
[246]Villarroel M J, Sancho E, Ferrando M D, et al. Effect of an Acaricide on the Reproduction and Survival of Daphnia magna[J]. Bulletin of Environmental Contamination and Toxicology,1999,63(2):167-173.
[247]Enriquez Garcia C, Nandini S, Sarma S S S. Demographic characteristics of the copepod Acanthocyclops americanus (Sars,1863) (Copepoda:Cyclopoida) fed mixed algal (Scenedesmus acutus)-rotifer (Brachionus havanaensis) diet[J]. Hydrobiologia,2011,666(1):59-69.
[248]Sarma S S S, Martinez-Jeronimo F, Ramirez-Perez T, et al. Effect of cadmium and chromium toxicity on the demography and population growth of Brachionus calyciflorus and Brachionus patulus (Rotifera)[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances & Environmental Engineering,2006,41(4):543-558.
[249]Sarma S S S, Pavon-Meza E L, Nandini S. Comparative population growth and life table demography of the rotifer Asplanchna girodi at different prey (Brachionus calyciflorus and Brachionus havanaensis) (Rotifera) densities[J]. Hydrobiologia,2003,491(1-3):309-320.
[250]Sarma S S S, Nandini S, Flores J L G. Effect of Methyl Parathion on the Population Growth of the Rotifer Brachionus patulus (O. F. Muller) under Different Algal Food (Chlorella vulgaris) Densities[J]. Ecotoxicology and Environmental Safety,2001,48(2):190-195.
[251]柯丽霞,席贻龙,查春旺,等.甲胺磷和17β-雌二醇对萼花臂尾轮虫实验种群动态的影响[J].应用生态学报,2008,19(1):157-162
[252]史清毅,汝少国,邴欣.久效磷对雄性孔雀鱼生殖毒性研究[J][J].安全与环境学报,2007,7(3):4-9.
[253]Brodkin M A, Madhoun H, Rameswaran M, et al. Atrazine is an immune disruptor in adult northern leopard frogs (Rana pipiens)[J]. Environmental Toxicology and Chemistry,2007,26(1):80-84.
[254]史清毅,汝少国,邴欣.久效磷对雄性孔雀鱼生殖毒性研究[J].安全与环境学报,2008,7(3):4-9.
[255]穆洪,张平,徐建,等.绿麦隆和阿特拉津联合染毒对小鼠睾丸的影响[J].环境与健康杂志,2007,24(1):43-44.
[256]Anderson T D, Lydy M J. Increased toxicity to invertebrates associated with a mixture of atrazine and organophosphate insecticides[J]. Environmental Toxicology and Chemistry,2002,21(7):1507-1514.
[257]高敏苓,戴树桂,张平.绿麦隆,阿特拉津单一与复合污染对蚯蚓的毒性效应研究[J].生态环境,2006,15(3):525-528.
[258]Snell T W, Hoff F H. Fertilization and male fertility in the rotifer Brachionus plicatilis. In:Rotifer Symposium IV; 1987:Springer; 1987.329-334.
[2]Harrison P T, Holmes P, Humfrey C D. Reproductive health in humans and wildlife:are adverse trends associated with environmental chemical exposure?[J]. Sci Total Environ,1997,205(2-3):97-106.
[3]周少奇,林云琴.环境激素污染研究进展[J].环境污染与防治,2004,26(1):25-27.
[4]包国章,董德明,李向林.环境雌激素生态影响的研究进展[J].生态学杂志,200 1,20(5):44-50.
[5]Magliulo L, Schreibman M P, Cepriano J e a. Endocrine disruption caused by two common pollutants at "acceptable"concentrations[J]. Neurotoxicology and Teratology,2002, (24):71-79.
[6]Takahashi, Higashitani, Yakou e a. Evaluating bioaccumulation of suspected endocrine disruptors into periphytons and benthos in the Tama River[J]. Water Science and Technology,2003,47(9):71-83.
[7]Zou E. Current status of environmental endocrine disruptionin selected aquatic invertebrates[J]. Acta Zoologica Sinica,,2003,49(5):551-565.
[8]Colborn T. Environmental estrogens:health implications for humans and wildlife[J]. Environmental Health Perspectives,1995,103(Suppl 7):135.
[9]杨再福,赵晓祥.环境雌激素对水生动物的影响研究进展[J].生态环境,2005,14(1):108-112.
[10]王杉霖,张剑波.中国环境内分泌干扰物的污染现状分析[J].环境污染与防治,2005,27(3):228-231.
[11]王毓秀,张利民,邹敏.化学农药与环境激素[J].农村生态环境,1999,15(4):37-41.
[12]刘玉成,刘玉斌,李太福.城市固体垃圾焚烧的二次污染控制实现技术[J].环境科学与技术,2006,29(5):97-99.
[13]刘苹.环境激素与人类健康[J].云南环境科学,2001,20(z1):42-45.
[14]薛南冬,王洪波,徐晓白.水环境中农药类内分泌干扰物的研究进展[J].科学通报,2005,50(22):2441-2449.
[15]任仁.环境激素的种类和污染途径[J].大学化学,2001,16(5):28-32.
[16]章志青.环境激素对人体健康的影响及其防制对策[J].绍兴文理学院学报,2004,24(7):109-112.
[17]McKinlay R, Plant J A, Bell J N B, et al. Endocrine disrupting pesticides: Implications for risk assessment[J]. Environment International,2008,34(2): 168-183.
[18]刘现明,徐学仁,张笑天,等.大连湾沉积物中的有机氯农药和多氯联苯[J].海洋环境科学,2001,20(4):40-44.
[19]魏渲辉,汝少国,姜明.有机磷农药对鱼类的毒性效应及内分泌扰乱作用[J].海洋科学,2002,26(9):27-31.
[20]邹晓平,杨丽,秦红,等.农村男性接触有机磷农药对精液质量影响的研究[J].中国计划生育学杂志,2006,13(8):476-478.
[21]王凌一,黎先春,殷月芬,等.菜州湾水体中有机磷农药的残留监测与风险影响评价[J].安全与环境学报,2007,7(3):83-85
[22]詹宁育,王心如.辛硫磷与氰戊菊酯对大鼠睾丸的联合毒性作用[J].中华劳动卫生职业病杂志,2001,19(4):261-264.
[23]姚克文,王介东.氰戊菊酯对大鼠精子及生殖激素的影响[J].生殖医学杂志,2008,17(1):58-61.
[24]薛南冬,徐晓白,刘秀芬.北京官厅水库中农药类内分泌干扰物分布和来源[J].环境科学,2006,27(10):2081-2086.
[25]任晋,蒋可.阿特拉津及其降解产物对张家口地区饮用水资源的影响[J].科学通报,2002,47(10):748-762.
[26]丁振华,贾洪武,刘彩娥,等.黄浦江沉积物重金属的污染及评价[J].环境科学与技术,2006,29(2):64-66.
[27]李敏,宗栋良.地表水中重金属类环境激素污染调查术[J].广州化工,2010,38(8):217-223
[28]邵兵,胡建英,杨敏.重庆流域嘉陵江和长江水环境中壬基酚污染状况调查[J].环境科学学报,2002,22(1):12-16.
[29]段菁春,陈兵,麦碧娴,等.洪季珠江三角洲水系烷基酚污染状况研究[J].环境科学,2004,25(3):48-52
[30]沈钢,张祖麟,余刚,等.夏季海河与渤海湾中壬基酚和辛基酚污染的状况[J].中国环境科学,2005,25(6):733-736.
[31]黄长江,董巧香,雷瓒,等.我国东南沿海3港口有机锡污染的调查[J].海洋学报,2005,27(1):57-63.
[32]高俊敏,胡建英,金晓辉,等.水环境中的有机锡污染调查[J].中国给水排水,2004,20(7):25-27.
[33]Waring R H, Harris R M. Endocrine disrupters:A human risk?[J]. Molecular and Cellular Endocrinology,2005,244(1-2):2-9.
[34]Chantana P, Bill L, Lasley A, et al. Reproductive hormone hrofile along pesticide factory workers[J]. JOEM,1998,40(12):1038-1047.
[35]Wolff M S, Toniolo P G. Environmental organochlorine exposure as a potential etiologic factor in breast cancer[J]. Environmental Health Perspectives,1995, 103(Suppl7):141-145.
[36]Ginsburg J, Okolo S, Prelevic G, et al. Residence in the London area and sperm density[J]. Lancet,1994,343(8891):230-230.
[37]McLachlan J A, Simpson E, Martin M. Endocrine disrupters and female reproductive health[J]. Best Practice & Research Clinical Endocrinology & Metabolism,2006,20(1):63-75.
[38]Friedmann A S. Atrazine inhibition of testosterone production in rat males following peripubertal exposure[J]. Reproductive Toxicology,2002,16(3): 275-279.
[39]Graymore M, Stagnitti F, Allinson G. Impacts of atrazine in aquatic ecosystems[J]. Environment International,2001,26(7-8):483-495.
[40]Ansar Ahmed S. The immune system as a potential target for environmental estrogens (endocrine disrupters):a new emerging field[J]. Toxicology,2000, 150(1-3):191-206.
[41]余增丽,张立实,徐培渝,等.三种增塑剂对乳腺癌细胞株MCF-7增殖的影响[J].中华预防医学杂志,2003,37(3):150-153.
[42]Miodovnik A, Engel S M, Zhu C, et al. Endocrine disruptors and childhood social impairment[J]. Neurotoxicology,2011,32(2):261-267.
[43]Purdom C E H PA, Bye VJ, et al. Estrogenic effects of effluents from sewage treatments works[J]. Chem Ecol,1994, (8):275-285.
[44]Larsson D GJ A M, Parkkonen J, et al. Ethinyloestradiol-an undesired fishc ontraceptive[J]. Aquatic Toxicol,1999, (45):91-97.
[45]Jobling S S D, Osborne J A, et al. Inhibition of testicular growth in rainbow trout (Oncorhynchus mykiss) exposed to estrogenic alkylphenolic chemicals[J]. Environ T oxicol Chem,1996, (15):194-202.
[46]Navas M, Wenzel, et al. Linear alkylbenzene sulfonates and intermediate products from their degradation are not estrogenic[J]. Marine Pollution Bulletin,1999:38:880-884.
[47]Yokoata, Miyashita, Yuasa. High glucuronidation activity of environmental estrogens in the carp (Cyprinus carpino) intestine[J]. Life Sciences,2002, (71): 887-898.
[48]Pedersen, Hill. Tissue distribution and depuration of 4-tert-octylphenol residues in the cyprinid fish[[J]. Scardinius Erythrophthalmus, Environ. Sci Technol, 2002, (36):3275-3283.
[49]赵兵,刘征涛,徐章法,等.酚类化合物对金鱼幼鱼的雌激素效应研究[J].环境科学学报,2005,25(9):1259-1264.
[50]吕雪飞,周群芳,宋茂勇,等.17β-雌二醇、壬基酚及其混合物对雄性泥鳅的雌激素效应[J].科学通报,2007,52(18):2122-2126.
[51]夏继刚,牛翠娟.壬基酚暴露对斑马鱼求偶行为与繁殖成功率的影响[J].生态学报,2010,30(20):5537-5543.
[52]Thomas P. Effects of Aroclor 1254 and cadmium on reproductive endocrine function and ovarian growth in Atlantic croaker[J]. Marine Environmental Research,1989,28(1):499-503.
[53]Christiansen L B, Pedersen K L, Korsgaard B, et al. Estrogenicity of xenobiotics in rainbow trout (Oncorhynchus mykiss) using in vivo synthesis of vitellogenin as a biomarker[J]. Marine Environmental Research,1998, 46(1-5):137-140.
[54]刘德英,张剑波,丁剑.我国农药类环境内分泌干扰物使用现状和对策[J].环境保护,2005,(6):45-50.
[55]孟昭璐,刘皓慈,戎奕,等.阿特拉津对斑马鱼影响的研究[J].职业与健康,2008,24(003):205-208.
[56]陈家长,孟顺龙,胡庚东,等.阿特拉津对雄性鲫鱼血清雌二醇含量的影响[J].生态学杂志,2007,26(7):1068-1073.
[57]Drevnick P E, Sandheinrich M B. Effects of dietary methylmercury on reproductive endocrinology of fathead minnows[J]. Environmental science and technology,2003,37(19):4390-4396.
[58]米兆娟,李杰.三丁基氯化锡对哺乳动物生殖毒性及作用机制[J].中国公共卫生,2007,23(3):364-366.
[59]Gibbs P E, Pascoe P L, Burt G R. Sex Change in the Female Dog-Whelk, Nucella Lapillus, Induced by Tributyltin from Antifouling Paints[J]. Journal of the Marine Biological Association of the United Kingdom,1988,68(04): 715-731.
[60]Bryan G W, Gibbs P E, Burt G R, et al. The effects of tributyltin (TBT) accumulation on adult dog-whelks, Nucella lapillus:long-term field and laboratory experiments[J]. Journal of the Marine Biological Association of the United Kingdom,1987,67(03):525-544.
[61]Oehlmann J, Schulte-Oehlmann U, Tillmann M, et al. Effects of Endocrine Disruptors on Prosobranch Snails (Mollusca:Gastropoda) in the Laboratory. Part I:Bisphenol A and Octylphenol as Xeno-Estrogens[J]. Ecotoxicology, 2000,9(6):383-397.
[62]Morcillo Y, Porte C. Evidence of Endocrine Disruption in the Imposex-Affected Gastropod Bolinus brandaris[J]. Environmental Research, 1999,81(4):349-354.
[63]赵松涛,袁星,于书霞.环境激素对水蚤的影响[J].环境污染与防治,2001,23(6):314-316.
[64]Haeba M H, Hilscherova K, Mazurova E, et al. Selected endocrine disrupting compounds (vinclozolin, flutamide, ketoconazole and dicofol):Effects on survival, occurrence of males, growth, molting and reproduction of Daphnia magna[J]. Environmental Science and Pollution Research,2008,15(3): 222-227.
[65]Dodson S I, Merritt C M, Torrentera L, et al. Dieldrin reduces male production and sex ratio in Daphnia galeata mendotae[J]. Toxicology and Industrial Health,1999,15(1-2):192-199.
[66]Olmstead A W, Leblanc G A. Juvenoid hormone methyl farnesoate is a sex determinant in the crustacean Daphnia magna[J]. Journal of Experimental Zoology,2002,293(7):736-739.
[67]Brown R J, Conradi M, Depledge M H. Long-term exposure to 4-nonylphenol affects sexual differentiation and growth of the amphipod Corophium volutator (Pallas,1766) [J]. Sci.Total Environ,1999, (233):77-88.
[68]Hutchinson T H, Pounds N A, Hampel M, et al. Life-cycle effects of 20-hydroxyecdysone and di-ethylstilbestrol on the marine copepod Tisbe battagliai[J]. Environ. Toxicol. Chem,1999, (18):2914-2920.
[69]Hutchinson T H, Pounds N A, Hampel M, et al. Impact of ecdysteroids and oestrogens on develop-mental and reproductive parameters in the marine copepod.Tisbe battagliai[J]. Sci.Total Environ,1999, (233):167-179.
[70]Andersen H R, L., Wollenberger B H, O.Kusk K. Development of copepod nauplii to copepodites:a parameter for chronic toxicity including endocrine disruption[J]. Environ.Toxicol.Chem,2001, (20):2821-2829.
[71]Breitholtz M, Bengtsson B E. Oestrogens have no hormonal effect on the development and reproduction of the harpacticoid copepod Nitocra spi nipes[J]. Mar.Pollut.Bul,2001,1(42):879-886.
[72]Gross M Y, Maycock D S, Thorndyke M C, et al. Abnormalities in sexual development of the amphipod Gammarus pulex (L.) found below sewage treatment works[J]. Environ. Toxicol. Chem,2001, (20):1792-1797.
[73]Billinghurst Z, Clare A S, T F. Inhibition of barnacle settlement by the environmental oestrogen 4-nonylphenol and the natural oestrogen 17 beta oestradio[J]. Mar Pollut Bull,1998,36(10):833-839.
[74]Billinghurst Z, Clare A S, Matsumura K, et al. Induction of cypris major protein in barnacle larvae by exposure to 4-n-nonylphenol and 17p-oestradiol[J]. Aquatic Toxicology,2000,47(3-4):203-212.
[75]Atienzar F A, Billinghurst Z, Depledge M H.4-n-Nonylphenol and 17-β estradiol may induce common DNA effects in developing barnacle larvae[J]. Environmental Pollution,2002,120(3):735-738.
[76]蔡立哲,厉红梅,邹朝中.深圳河口福田泥滩海洋线虫的种类组成及季节变化[J].生物多样性,2000,8(4):385-390.
[77]王硕治,汝少国,杜恩在.化学物质对自由生活线虫毒性效应生物标志物研究进展[J].科技导报,2007,18(18):75-80.
[78]Tominaga N, Kunimoto M, Kai T, et al. A Convenient Assay for Evaluating Chemical Toxicity Using Caenorhabditis elegans as a Model Organism-Application to Alkylphenol Toxicity Test-[J]. Environ Sci,2003, 10(4):215-221.
[79]Kohra S, Tominaga N, Mitsui Y, et al. Determination of a screening system of endocrine disruptors by the induction of vitellogenin mRNA in C. elegans larvae[J]. Japanese Journal of Toxicology & Environmental Health,1999,45.
[80]王摆,汝少国,王蔚.久效磷对细小色矛线虫胚胎发育和繁殖的影响[J].中国环境科学,2009,29(5):543-547.
[81]田雨,汝少国.久效磷对秀丽隐杆线虫(Caenorhabditis elegans)胁迫相关基因mRNA表达的影响[J].中国海洋大学学报,2012.42(3):35-42.
[82]Starkweather P L. Rotifera,in animal energetics.Vol.1.Protozoa through insecta,Pandian TJ and Verberg FJ(Eds)[J]. Academic Press,Orlando, FL, 1987.
[83]Wallace RL S T. Rotifera,in Thorp JH,Covich AP.(eds.).Ecology and systematics of North Americal freshwater invertebrates[J]. Acedamic presss,New York,,1991:187-248.
[84]Gilbert J J. Timing of diapause in monogonont rotifers:Machanisms and strategies.In:Alekseev VR, De Stasio B, Gilbert JJ, editor. Diapause in Aquatic Invertebrates:Theory and Human use.Dordrecht:Springer pp. 11-27[J].2007.
[85]Birky C W, Gilbert J J. Parthenogenesis in rotifers:The control of sexual and asexual reproduction [J]. Am. Zool,1971, (11):245-246.
[86]Pourriot R, Snell T W. Resting eggs in rotifers[J]. Hydrobiologia,1983,104(1): 213-224.
[87]Gilbert J J. Environmental and endogenous control of sexuality in a rotifer life cycle:developmental and population biology[J]. Evolution & Development, 2003,5(1):19-24.
[88]Snell T W, Kubanek J, Carter W, et al. A protein signal triggers sexual reproduction in Brachionus plicatilis (Rotifera)[J]. Marine Biology,2006, 149(4):763-773.
[89]Snell T. Sex, population dynamics and resting egg production in rotifers[J]. Hydrobiologia,1987,144(2):105-111.
[90]Azuara-Garcia R, Sarma S S S, Nandini S. The combined effects of zinc and alga on the life table demography of Anuraeopsis fissa and Brachionus rublens (Rotifera)[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances & Environmental Engineering,2006,41(4): 559-572.
[91]Snell T W, Moffat B D. A 2-d Life cycle test with the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1992,11(9): 1249-1257.
[92]Snell T W, Janssen C R. Rotifers in ecotoxicology:A review[J]. Hydrobiologia, 1995,313-314(0):231-247.
[93]Schaefer E D, Pipes W O. Temperature and the toxicity of chromate and arsenate to the rotifer philodina roseola.[J]. Water Res.,1973, (7):1781-1790.
[94]Snell T W, Persoone G. Acute toxicity bioassays using rotifers. Ⅱ. A freshwater test with Brachionus rubens[J]. Aquatic Toxicology,1989,14(1):81-91.
[95]Charoy C, Janssen C R. The swimming behaviour of Brachionus calyciflorus (rotifer) under toxic stress. II. Comparative sensitivity of various behavioural criteria[J]. Chemosphere,1999,38(14):3247-3260.
[96]Ramirez-Perez T, Sarma S S S, Nandini S. Effects of mercury on the life table demography of the rotifer Brachionus calyciflorus pal las (rotifera)[JJ. Ecotoxicology,2004,13(6):535-544.
[97]Snell T W, Joaquim-Justo C. Workshop on rotifers in ecotoxicology[J]. Hydrobiologia,2007,593:227-232.
[98]Snell T W, Carmona M J. Surface glycoproteins in copepods:Potential signals for mate recognition[J]. Hydrobiologia,1994,292-293(0):255-264.
[99]Snell T W. Chemical ecology of rotifers[J]. Hydrobiologia,1998,387-388(0): 267-276.
[100]Snell T W, Shearer T L, Smith H A, et al. Genetic determinants of mate recognition in Brachionus manjavacas (Rotifera)[J]. Bmc Biology,2009,7.
[101]金解敏,杨家新,陈立侨.铜锌离子对褶皱臂尾轮虫的急性毒性试验[J]. 水产科技情报,1999,26(3):121-123.
[102]Xi Y L, Hu H Y. Effect of thiophanate-methyl on the reproduction and survival of the freshwater rotifer Brachionus calyciflorus pallas[J]. Bulletin of Environmental Contamination and Toxicology,2003,71(4):722-728.
[103]Halbach U. Population dynamics of rotifers and its consequences for ecotoxicology[J]. Hydrobiologia,1984,109(1):79-96.
[104]Halbach U, Siebert M, Westermayer M, et al. Population ecology of rotifers as a bioassay tool for ecotoxicological tests in aquatic environments[J]. Ecotoxicology and environmental safety,1983,7(5):484-513.
[105]Snell T W, Persoone G. Acute toxicity bioassays using rotifers. I. A test for brackish and marine environments with Brachionus plicatilis[J]. Aquatic Toxicology,1989,14(1):65-80.
[106]Snell T W, Moffat B D, Janssen C, et al. Acute toxicity tests using rotifers. IV. Effects of cyst age, temperature, and salinity on the sensitivity of Brachionus calyciflorus[J]. Ecotoxicology and Environmental Safety,1991,21(3): 308-317.
[107]Ferrando M D, Andreu-Moliner E. Acute lethal toxicity of some pesticides to Brachionus calyciflorus and Brachionus plicatilis[J]. Bulletin of Environmental Contamination and Toxicology,1991,47(3):479-484.
[108]Fernandez-Casalderry A, Ferrando M D, Andreu-Moliner E. Acute toxicity of several pesticides to rotifer (Brachionus calyciflorus)[J]. Bulletin of Environmental Contamination and Toxicology,1992,48(1):14-17.
[109]Snell T W, Childress M J, Boyer E M, et al. Assessing the status of rotifer mass cultures[J]. J.World Aquacult.Soc,,1987, (18):270-277.
[110]Janssen C R, Ferrando M D, Persoone G. Ecotoxicological Studies with the Freshwater Rotifer Brachionus calyciflorus:Ⅳ. Rotifer Behavior as a Sensitive and Rapid Sublethal Test Criterion[J]. Ecotoxicology and Environmental Safety,1994,28(3):244-255.
[111]Janssen C R, Ferrando M D, Persoone G. Ecotoxicological Studies with the Freshwater Rotifer Brachionus calyciflorus:Ⅰ.Conceptual framework and applications[J]. Hydrobiologia,1993, (255/256):21-32.
[112]Beauvais J E, Enesco H E. Life span and age-related changes in activity level of the rotifer Asplanchna brightwelli:influence of curare[J]. Experimental gerontology,1985,20(6):359-366.
[113]Charoy C P, Janssen C R, Persoone Q et al. The swimming behaviour of Brachionus calyciflorus (rotifer) under toxic stress. I. The use of automated trajectometry for determining sublethal effects of chemicals[J]. Aquatic Toxicology,1995,32(4):271-282.
[114]Snell T W. Rotifer Ingestion Test for Rapid Assessment of Toxicity. In:Blaise C, Ferard J-F, eds. Small-scale Freshwater Toxicity Investigations:Springer Netherlands; 2005:323-335.
[115]Starkweather P L, Gilbert J J. Feeding in the rotifer Brachionus calyciflorus[J]. Oecologia,1977,28(2):133-139.
[116]Schlosser H, Anger K. The significance of some methodological effects on filtration and ingestion rates of the rotife Brachionus plicatilis[J]. Helgoland Marine Research,1982,35(2):215-225.
[117]Starkweather P L, Gilbert J J, Frost T M. Bacterial feeding by the rotifer Brachionus calyciflorus clearance and ingestion rates, behavior and population dynamics[J]. Oecologia,1979,44(1):26-30.
[118]Juchelka C M, Snell T W. Rapid toxicity assessment using rotifer ingestion rate[J]. Archives of Environmental Contamination and Toxicology,1994, 26(4):549-554.
[119]Juchelka C M, Snell T W. Rapid toxicity assessment using ingestion rate of cladocerans and ciliates[J]. Archives of Environmental Contamination and Toxicology,1995,28(4):508-512.
[120]徐晓平,席贻龙,储昭霞,等.溴氰菊酯对萼花臂尾轮虫实验种群动态的影响[J].动物学报,2005,51(2):251-256.
[121]储昭霞,席贻龙,徐晓平,等.除草剂草甘膦对萼花臂尾轮虫生活史特征的影响[J].应用生态学报,2005,16(6):1142-1145.
[122]Huang L, Xi Y L, Zha C W, et al. Effect of aldrin on life history characteristics of rotifer Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2007,79(5):524-528.
[123]Marcial H S, Hagiwara A. Effect of diazinon on life stages and resting egg hatchability of rotifer Brachionus plicatilis[J]. Hydrobiologia,2007,593: 219-225.
[124]Ferrando M D, Janssen C R, Andreu E, et al. Ecotoxicological studies with the freshwater rotifer Brachionus calyciflorus II. An assessment of the chronic toxicity of lindane and 3,4-dichloroaniline using life tables[J]. Hydrobiologia, 1993,255-256(1):33-40.
[125]Ramakrishna Rao T, Sarma S S S. Demographic parameters of Brachionus patulus Muller (Rotifera) exposed to sublethal DDT concentrations at low and high food levels[J]. Hydrobiologia,1986,139(3):193-200.
[126]Fernandez-Casalderrey A, Ferrando M D, Andreu-Moliner E. Demographic parameters of Brachionus calyciflorus Pallas (Rotifers) exposed to sublethal endosulfan concentrations[J]. Hydrobiologia,1991,226(2):103-110.
[127]Zha C W, Xi Y L, Huang L, et al. Effect of sublethal exposure to chlordecone on life history characteristics of freshwater rotifer Brachionus calyciflorus pallas[J]. Bulletin of Environmental Contamination and Toxicology,2007, 78(1):71-75.
[128]Sarma S S S, Nandini S, Flores J L G. Effect of methyl parathion on the population growth of the rotifer Brachionus patulus (O. F. Muller) under different algal food (Chlorella vulgaris) densities[J]. Ecotoxicology and Environmental Safety,2001,48(2):190-195.
[129]Belgis C, Guido P. Cyst-based toxicity tests. XI. Influence of the type of food on the intrinsic growth rate of the rotifer Brachionus calyciflorus in short-chronic toxicity tests[J]. Chemosphere,2003,50(3):365-372.
[130]Belgis C, Persoone G Cyst-based toxicity tests XVII-Prefeeding advantages in short-chronic rotifer microbiotests[J]. Ecotoxicology and Environmental Safety,2005,60(1):73-80.
[131]Janssen C R, Persoone G, Snell T W. Cyst-base toxicity tests:VIII. Short-chronic toxicity tests with the freshwater rotifer Brachionus calyciflorus[J]. Aquatic Toxicology (Amsterdam),1994,28(3-4):243-258.
[132]Preston B L, Snell T W, Robertson T L, et al. Use of freshwater rotifer Brachionus calyciflorus in screening assay for potential endocrine disruptors[J]. Environmental Toxicology and Chemistry,2000,19(12): 2923-2928.
[133]Radix P, Severin Q Schramm K W, et al. Reproduction disturbances of Brachionus calyciflorus (rotifer) for the screening of environmental endocrine disrupters[J]. Chemosphere,2002,47(10):1097-1101.
[134]Sarma S S S, Ramiez-Perez T, Nandini S, et al. Combined Effects of Food Concentration and the Herbicide 2,4-Dichlorophenoxyacetic Acid on the Population Dynamics of Brachionus patulus (Rotifera)[J]. Ecotoxicology, 2001,10(2):91-99.
[135]Gama Flores J L, Sarma S S S, Fernandez Araiza M A. Combined Effects of Chlorella;Density and Methyl Parathion Concentration on the Population Growth of Brachionus calyciflorus(Rotifera)[J]. Bulletin of Environmental Contamination and Toxicology,1999,62(6):769-775.
[136]Preston B L, Snell T W. Full life-cycle toxicity assessment using rotifer resting egg production:implications for ecological risk assessment[J]. Environmental Pollution,2001,114(3):399-406.
[137]Snell T W, Janssen C R. Comparative toxicant sensitivity of sexual and asexual reproduction in the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1995,14(3):415-420.
[138]Marcial H, Hagiwara A, Snell T. Effect of some pesticides on reproduction of rotifer Brachionus plicatilis Miiller. In:Herzig A, Gulati R, Jersabek C et al., eds. Rotifera X:Springer Netherlands; 2005:569-575.
[139]Snell T W, Carmona M J. Comparative toxicant sensitivity of sexual and asexual reproduction in the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1995,14(3):415-420.
[140]Gallardo W G, Hagiwara A, Tomita Y, et al. Effect of some vertebrate and invertebrate hormones on the population growth, mictic female production, and body size of the marine rotifer Brachionus plicatilis Muller[J]. Hydrobiologia,1997,358(0):113-120.
[141]Xi Y L, Feng L K. Effects of Thiophanate-Methyl and Glyphosate on Asexual and Sexual Reproduction in the Rotifer Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2004,73(4): 644-651.
[142]Marcial H S, Hagiwara A, Snell T W. Effect of some pesticides on reproduction of rotifer Brachionus plicatilis Muller[J]. Hydrobiologia,2005, 546:569-575.
[143]Snell T W, DesRosiers N J D. Effect of progesterone on sexual reproduction of Brachionus manjavacas (Rotifera)[J]. Journal of Experimental Marine Biology and Ecology,2008,363(1-2):104-109.
[144]Sarma S S S, Brena-Bustamante P, Nandini S. Body size and population growth of Brachionus patulus (Rotifera) in relation to heavy metal (copper and mercury) concentrations[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances & Environmental Engineering,2008, 43(5):547-553.
[145]Sarma S S S, Gulati R D, Nandini S. Factors affecting egg-ratio in planktonic rotifers[J]. Hydrobiologia,2005,546:361-373.
[146]Moffat B D, Snell T W. Rapid toxicity assessment using an in vivo enzyme test for Brachionus plicatilis (Rotifera)[J]. Ecotoxicology and Environmental Safety,1995,30(1):47-53.
[147]Burbank S E, Snell T W. Rapid toxicity assessment using esterase biomarkers in Brachionus calyciflorus (Rotifera)[J]. Environmental Toxicology and Water Quality,1994,9(3):171-178.
[148]Rios-Arana J V, Gardea-Torresdey J L, Webb R, et al. Heat shock protein 60 (HSP60) response of Plationus patulus (Rotifera:Monogononta) to combined exposures of arsenic and heavy metals[J]. Hydrobiologia,2005,546:577-585.
[149]Kim R-O, Rhee J-S, Won E-J, et al. Ultraviolet B retards growth, induces oxidative stress, and modulates DNA repair-related gene and heat shock protein gene expression in the monogonont rotifer, Brachionus sp[J]. Aquatic Toxicology,2011,101(3-4):529-539.
[150]Smith H A, Burns A R, Shearer T L, et al. Three heat shock proteins are essential for rotifer thermotolerance[J]. Journal of Experimental Marine Biology and Ecology,2012,413:1-6.
[151]Cochrane B J, Irby R B, Snell T W. Effects of copper and tributyltin on stress protein abundance in the rotifer Brachionus plicatilis[J]. Comparative Biochemistry and Physiology Part C:Comparative Pharmacology,1991, 98(2-3):385-390.
[152]Wheelock C E, Wolfe M F, Olsen H, et al. Hsp60-induced tolerance in the rotifer Brachionus plicatilis exposed to multiple environmental contaminants[J]. Archives of Environmental Contamination and Toxicology, 1999,36(3):281-287.
[153]Wheelock C E, Baumgartner T A, Newman J W, et al. Effect of nutritional state on Hsp60 levels in the rotifer Brachionus plicatilis following toxicant exposure[J]. Aquatic Toxicology,2002,61(1-2):89-93.
[154]Snell T, Joaquim-Justo C. Workshop on rotifers in ecotoxicology[J]. Hydrobiologia,2007,593(1):227-232.
[155]Dahms H-U, Hagiwara A, Lee J-S. Ecotoxicology, ecophysiology, and mechanistic studies with rotifers[J]. Aquatic Toxicology,2011,101(1):1-12.
[156]ASTM. Standard guide for acute toxicity tests with the rotifer Brachionus. Annual Book of ASTM Standards vol.11.04, E1440.Philadelphia,PA,USA:American Society for Testing and Material.[J]. 1991.
[157]Gallardo W G, Hagiwara A, Tomita Y, et al. Effect of some vertebrate and invertebrate hormones on the population growth, mictic female production, and body size of the marine rotifer Brachionus plicatilis Muller[S]. Hydrobiologia,1997,358(1):113-120.
[158]Zhu W G G R X, Yang J X. Effect of endocrine disruptors fenvalerate and TBTC on reproduction of rotifer Brachionus calyciflorus[J]. Acta Ecologica Sinica,2009,29(7):3605-3612.
[159]Yang J, Snell T W. Effects of Progesterone, Testosterone, and Estrogen on Sexual Reproduction of the Rotifer Brachionus calyciflorus[J]. International Review of Hydrobiology,2010,95(6):441-449.
[160]张琴,包丽颖,刘伟江,等.我国饮用水水源内分泌干扰物的污染现状分析[J].环境科学与技术,2011,34(2):91-96.
[161]覃丹丹,袁伟,高尔生.双酚A对雄性生殖功能影响的研究进展[J].环境与健康杂志,2008,24(7):550-552.
[162]Izumi N, Yanagibori R, Shigeno S, et al. Effects of bisphenol A on the development, growth, and sex ratio of the housefly Musca domestica[J]. Environmental Toxicology and Chemistry,2008,27(6):1343-1353.
[163]Lemos M F L, van Gestel C A M, Soares A M V M. Endocrine disruption in a terrestrial isopod under exposure to bisphenol A and vinclozolin[J]. Journal of Soils and Sediments,2009,9(5):492-500.
[164]Anonymous. Methods of measuring the acute toxicity of effluents to freshwater and marine organisms. [J]. Environ-ment Protection Agency EPA/600/4-85/013.,1985.
[165]Zhang Z.S, X.F. H. Method for Study on Freshwater Plankton.Beijing:Science Press.410-411(in Chinese).[J].1991.
[166]Finley D J. Probit analysis.3rd ed[J]. Cambridge Univ. Press, London,1971.
[167]Walz N. Individual culture and experimental population dynamics of Keratella cochlearis (Rotatoria)[J]. Hydrobiologia,1983,107(1):35-45.
[168]Korstad J, Olsen Y, Vadstein O. Life history characteristics of Brachionus plicatilis (rotifera) fed different algae[J]. Hydrobiologia,1989,186-187(1): 43-50.
[169]Schmid-Araya J M. The effect of food concentration on the life histories of Brachionus plicatilis (O. F. M.) and Encentrum linnhei Scott[J]. Archiv fur Hydrobiologie,1991,121(1):87-102.
[170]Krebs C J. Ecology. The Experimental Analysis of Distribution and Abundance. Harper and Row, New York.[J].1985.
[171]刘红玲,刘晓华,王晓祎,等.双酚A和四溴双酚A对大型溞和斑马鱼的毒性[J].环境科学,2007,(8):184-1787
[172]郭匿春,谢平.双酚A和壬基酚对隆线溞和微型裸腹溞的毒性[J].水生生物学报,2009,(3):492-497
[173]孙小娜,李晓彩,马爱团,等.双酚A对雄性小鼠睾丸发育和生殖激素分泌水平的影响[J].中国兽医科学,2010,40(009):949-952.
[174]黄晔,任华,孙竹筠,等.壬基酚和双酚A对雄性斑马鱼(Danio rerio)卵黄蛋白原mRNA的诱导效应[J].生态毒理学报,2008,3(3):274-279.
[175]雷忻,李宗强,廉振民,等.双酚A和对硝基酚对泥鳅的急性毒性效应[J].生态学杂志,2009,28(11):2257-2261.
[176]端正花,朱琳,王平,等.双酚A对斑马鱼不同发育阶段的毒性及机理[J].环境化学,2007,(4):491-494
[177]Galkovskaja G Planktonic rotifers and temperature[J]. Hydrobiologia,1987, 147(1):307-317.
[178]Awaiss A, Kestemont P. An investigation into the mass production of the freshwater rotifer Brachionus calyciflorus Pallas.2. Influence of temperature on the population dynamics[J]. Aquaculture,1992,105(3):337-344.
[179]Yoshinaga T, Hagiwara A, Tsukamoto K. Effect of conditioned media on the asexual reproduction of the monogonont rotifer Brachionus plicatilis O.F. Muller[J]. Hydrobiologia,1999, (412):103-110.
[180]Pourriot R. Les rotiferes biologie. [J]. Aquaculture,1986,5:201-221.
[181]Janssen C R, Ferrando Rodrigo M D, Persoone G Ecotoxicological studies with the freshwater rotifer, Brachionus calyciflorus[J]. Hydrobiologia,1993, 255-256(1):21-32.
[182]Huang L, Xi Y L, Zha C W, et al. Effect of Aldrin on Life History Characteristics of Rotifer, Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2007,79(5):524-528.
[183]Ramakrishna Rao T, Sarma S. Demographic parameters of Brachionus patulus Muller (Rotifera) exposed to sublethal DDT concentrations at low and high food levels[J]. Hydrobiologia,1986,139(3):193-200.
[184]Huang Y Q, Wong C K C, Zheng J S, et al. Bisphenol A (BPA) in China:A review of sources, environmental levels, and potential human health impacts[J]. Environment International,2012,42(0):91-99.
[185]Fukuhori N, Kitano M, Kimura H. Toxic Effects of Bisphenol A on Sexual and Asexual Reproduction in Hydra oligactis[J]. Archives of Environmental Contamination and Toxicology,2005,48(4):495-500.
[186]Kwak H-I, Bae M-O, Lee M-H, et al. Effects of nonylphenol, bisphenol a, and their mixture on the viviparous swordtail fish (Xiphophorus helleri)[J]. Environmental Toxicology and Chemistry,2001,20(4):787-795.
[187]Gallardo W G, Hagiwara A, Snell T W. Effect of juvenile hormone and serotonin (5-HT) on mixis induction of the rotifer Brachionus plicatilis Muller[J]. Journal of Experimental Marine Biology and Ecology,2000,252(1): 97-107.
[188]Fernandez-Casalderrey A, Ferrando M, Andreu-Moliner E. Demographic parameters of Brachionus calyciflorus Pallas (Rotifers) exposed to sublethal endosulfan concentrations[J]. Hydrobiologia,1991,226(2):103-110.
[189]Fernandez-Casalderry A, Ferrando M D, Andreu-Moliner E. Acute toxicity of several pesticides to rotifer(Brachionus calyciflorus)[S]. Bulletin of Environmental Contamination and Toxicology,1992,48(1):14-17.
[190]Sohoni P, Tyler C, Hurd K, et al. Reproductive effects of long-term exposure to bisphenol A in the fathead minnow (Pimephales promelas)[J]. Environmental science & technology,2001,35(14):2917-2925.
[191]Kang J-H, Aasi D, Katayama Y. Bisphenol A in the aquatic environment and its endocrine-disruptive effects on aquatic organisms[J]. CRC Critical Reviews in Toxicology,2007,37(7):607-625.
[192]黄晔,任华,孙竹筠,等.壬基酚和双酚A对雄性斑马鱼(Danio rerio)卵黄蛋白原mRNA的诱导效应[J].生态毒理学报,2008,3(3):274-279.
[193]Snell T W, Moffat B D. A 2-d Life cycle test with the rotifer Brachionus calyciflorus[J]. Environmental Toxicology and Chemistry,1992,11(9): 1249-1257.
[194]Xi Y L, Feng L K. Effects of thiophanate-methyl and glyphosate on asexual and sexual reproduction in the rotifer Brachionus calyciflorus Pallas[J]. Bulletin of Environmental Contamination and Toxicology,2004,73(4): 644-651.
[195]Ke L-X, Xi Y-L, Zha C-W, et al. Effects of three organophosphorus pesticides on population growth and sexual reproduction of rotifer Brachionus calyciflorus Pallas[J]. Acta Ecologica Sinica,2009,29(3):182-185.
[196]乔坤,刘媛媛,李玉华,等.双酚A斑马鱼雄性生殖毒性的表观遗传学基础[J].实验动物与比较医学,2012,32(1):30-37.
[197]Siebers J, Gottschild D, Nolting H-G. Pesticides in precipitation in northern Germany[J]. Chemosphere,1994,28(8):1559-1570.
[198]Donna A, Betta P-G, Robutti F, et al. Ovarian mesothelial tumors and herbicides:a case-control study[J]. Carcinogenesis,1984,5(7):941-942.
[199]Cooman K, Debels P, Gajardo M, et al. Use of Daphnia spp. for the ecotoxicological assessment of water quality in an agricultural watershed in south-central Chile[J]. Archives of Environmental Contamination and Toxicology,2005,48(2):191-200.
[200]Hayes T B, Khoury V, Narayan A, et al. Atrazine induces complete feminization and chemical castration in male African clawed frogs (Xenopus laevis)[J]. Proceedings of the National Academy of Sciences of the United States of America,2010,107(10):4612-4617.
[201]Tillitt D E, Papoulias D M, Whyte J J, et al. Atrazine reduces reproduction in fathead minnow (Pimephales promelas)[J]. Aquatic Toxicology,2010,99(2): 149-159.
[202]Marcial H S, Hagiwara A. Effect of diazinon on life stages and resting egg hatchability of rotifer Brachionus plicatilis[J]. Hydrobiologia,2007,593(1): 219-225.
[203]Xi Y L, Huang X F, Jin H J. Life history characteristics of three types of females in Brachionus calyciflorus Pallas (Rotifera) fed different algae[J]. Hydrobiologia,2001,446:95-98.
[204]Fernandez-Casalderrey A, Ferrando M, Andreu-Moliner E. Effect of sublethal diazinon concentrations on the demographic parameters of Brachionus calyciflorus Pallas (Rotifera)[J]. Bulletin of Environmental Contamination and Toxicology,1992,48(2):202-208.
[205]Fernandez-Casalderrey A, Ferrando M D, Andreu-Moliner E. Endosulfan and diazinon toxicity to the freshwater rotifer Brachionus calyciflorus[J].Journal of environmental science and health. Part. B, Pesticides, food contaminants, and agricultural wastes,1992,27(2):155-164.
[206]Giddings J M, Biever R C, Annuziato M E, et al. Effects of diazinon on large outdoor pond microcosms[J]. Environmental Toxicology and Chemistry,1996, 15(5):618-629.
[207]Gentile J H, Gentile S M, Hairston N G, et al. The use of life-tables for evaluating the chronic toxicity of pollutants to Mysidopsis bahia [J]. Hydrobiologia,1982,93(1):179-187.
[208]Day K, Kaushik N K. An assessment of the chronic toxicity of the synthetic pyrethroid, fenvalerate, to Daphnia galeata mendotae, using life tables[J]. Environmental Pollution,1987,44(1):13-26.
[209]Janssen C, Persoone G, Snell T. Cyst-based toxicity tests. Ⅷ. Short-chronic toxicity tests with the freshwater rotifer Brachionus calyciflorus[J]. Aquatic Toxicology,1994,28(3):243-258.
[210]Sanchez M, Ferrando M D, Sancho E, et al. Assessment of the toxicity of a pesticide with a two-generation reproduction test using Daphnia magna[J]. Comparative Biochemistry and Physiology Part C:Pharmacology, Toxicology and Endocrinology,1999,124(3):247-252.
[211]Palma P, Palma V, Matos C, et al. Effects of atrazine and endosulfan sulphate on the ecdysteroid system of Daphnia magna[J]. Chemosphere,2009,74(5): 676-681.
[212]Vandenbergh G F, Adriaens D, Verslycke T, et al. Effects of 17a-ethinylestradiol on sexual development of the amphipod Hyalella azteca[J]. Ecotoxicol. Environ. Saf.,2003,54(216-222).
[213]Cleuvers M, Goser B, Ratte H-T. Life-strategy shift by intraspecific interaction in Daphnia magna:change in reproduction from quantity to quality[J]. Oecologia,1997,110(3):337-345.
[214]叶伟红,刘维屏,谭亚军.氟氯菊酯对大型蚤的亚慢性毒性及其恢复实验[J].农药,2004,43(2):86-89.
[215]Zou E, Bu S. Acute toxicity of copper, cadmium, and zinc to the water flea, Moina irrasa (Cladocera)[J]. Bulletin of Environmental Contamination and Toxicology,1994,52(5):742-748.
[216]Hayashi Y, Heckmann L-H, Callaghan A, et al. Reproduction recovery of the crustacean Daphnia magna after chronic exposure to ibuprofen[J]. Ecotoxicology,2008,17(4):246-251.
[217]乔广浩,刘欣.杀虫剂西维因毒性及雌激素活性进展研究[J].环境科学与技术,2010,33(002):99-105.
[218]Boran M, Altinok I, Capkin E, et al. Acute toxicity of carbaryl, methiocarb, and carbosulfan to the rainbow trout (Oncorhynchus mykiss) and guppy (Poecilia reticulata)[J]. Turkish Journal of Veterinary & Animal Sciences, 2007,31(1):39-45.
[219]Todd N E, Van Leeuwen M. Effects of Sevin (carbaryl insecticide) on early life stages of zebrafish (Danio rerio)[J]. Ecotoxicology and Environmental Safety,2002,53(2):267-272.
[220]Tripathi P K, Singh A. Carbaryl induced alterations in the reproduction and metabolism of freshwater snail Lymnaea acuminata[J]. Pesticide Biochemistry and Physiology,2004,79(1):1-9.
[221]Tripathi P K, Singh A. Toxic effects of dimethoate and carbaryl pesticides on reproduction and related enzymes of the freshwater snail Lymnaea acuminata[J]. Bulletin of Environmental Contamination and Toxicology,2003, 71(3):535-542.
[222]李燕南,谈立峰,孙雪照,等.职业暴露甲萘威对女性生殖内分泌的影响[J].中国工业医学杂志,2005,18(3):163-165.
[223]Hanazato T. Effects of long-and short-term exposure to carbaryl on survival, growth and reproduction of Daphnia ambigua[J]. Environmental Pollution, 1991,74(2):139-148.
[224]Cerbin S, Kraak M H S, de Voogt P, et al. Combined and single effects of pesticide carbaryl and toxic Microcystis aeruginosa on the life history of Daphnia pulicaria[J]. Hydrobiologia,2010,643:129-138.
[225]Sakamoto M, Chang K H, Hanazato T. Differential sensitivity of a predacious cladoceran (Leptodora) and its prey (the cladoceran Bosmina) to the insecticide carbaryl:Results of acute toxicity tests[J]. Bulletin of Environmental Contamination and Toxicology,2005,75(1):28-33.
[226]Hanazato T, Yasuno M. Effects of a carbamate insecticide, carbaryl, on the summer phyto-and zooplankton communities in ponds[J]. Environmental Pollution,1987,48(2):145-159.
[227]Xi Y L, Huang X F, Jin H J, et al. The effect of food concentration on the life history of three types of Brachionus calyciflorus females[J]. International Review of Hydrobiology,2001,86(2):211-217.
[228]Moore A, Waring C. Sublethal effects of the pesticide Diazinon on olfactory function in mature male Atlantic salmon parr[J]. Journal of Fish Biology,1996, 48(4):758-775.
[229]Hanazato T. Pesticide effects on structure of zooplankton community and functioning of lake ecosystem[J]. Acta Hydrobiologica Sinica,1997, 21(SUPPL.):22-28.
[230]Lionetto M G, Caricato R, Erroi E, et al. Carbonic anhydrase-based environmental bioassay[J]. International Journal of Environmental Analytical Chemistry,2005,85(12-13):895-903.
[231]Bielza P, Fernandez E, Gravalos C, et al. Carbamates Synergize the Toxicity of Acrinathrin in Resistant Western Flower Thrips (Thysanoptera: Thripidae)[J]. Journal of Economic Entomology,2009,102(1):393-397.
[232]Snell T W, Janssen C R. Rotifers in ecotoxicology:a review[J]. Hydrobiologia, 1995,313-314(1):231-247.
[233]A.Ferna ndez-Casalderry, M.D.Ferrando a E, Andreu-Moliner. Acute Toxicity of Several Pesticides to Rotifer(Brachionus calyciflorus) [J]. Bull. Environ. Contain. Toxicol,1992, (48):14-17.
[234]Sarma S S S, Jurado P S L, Nandini S. Effect of three food types on the population growth of Brachionus calyciflorus and Brachionus patulus (Rotifera:Brachionidae)[J]. Revista De Biologia Tropical,2001,49(1):77-84.
[235]Gilbert J J. Effect of food concentration on the production and viability of resting eggs of the rotifer Brachionus:implications for the timing of sexual reproduction[J]. Freshwater Biology,2010,55(12):2437-2446.
[236]Hagiwara A, Hino A. Effect of incubation and preservation on resting egg hatching and mixis in the derived clones of the rotifer Brachionus plicatilis[J]. Hydrobiologia,1989,186-187(1):415-421.
[237]Hagiwara A, Hino A, Hirano R. Effect of temperature and chlorinity on resting egg formation in the rotifer Brachionus plicatilis[J]. Nippon Suisan Gakkaishi,1988, (54):569-575.
[238]Lindley J A, P.Donkin, S.V.Evans, et al. Effects of two organochlorine compounds on hatching and viability of calanoid copepod eggs[J]. Journal of Experimental Marine Biology and Ecology,1999,242:59-74.
[239]Snell T W, M.Serra, M.J.Carmona. Toxicity and sexual reproduction in rotifers:Reduced resting egg production and heterozygosity loss In Forbes,V.E.(ed)[J]. Genetics and Ecotoxicology,1999, (Taylor and Francis): 169-185.
[240]Snell T W, Serra M. Using probability of extinction to evaluate the ecological significance of toxicant effects[J]. Environmental Toxicology and Chemistry, 2000,19(9):2357-2363.
[241]邴欣,汝少国,姜明.久效磷对金鱼的环境雌激素效应的研究[J].高技术通讯,2007,16(11):1195-1199.
[242]Wang L, Ye W, Zhou S, et al. Acute and chronic toxicity of organophosphate monocrotophos to Daphnia magna[J]. Journal of Environmental Science and Health, Part B,2009,44(1):38-43.
[243]Rao J V, Gunda V, Srikanth K, et al. Acute toxicity bioassay using Paramecium caudatum, a key member to study the effects of monocrotophos on swimming behaviour, morphology and reproduction[J]. Toxicological and Environmental Chemistry,2007,89(2):307-317.
[244]Joshi U M, Desai A K. Biochemical changes in the liver of fish, Tilapia mossambica (Peters), during continuous exposure to monocrotophos[J]. Ecotoxicology and Environmental Safety,1988,15(3):272-276.
[245]Gallardo W G, Hagiwara A, Snell T W. GABA enhances reproduction of the rotifer Brachionus plicatilis Muller:application to mass culture[J]. Aquaculture Research,2000,31(8-9):713-718.
[246]Villarroel M J, Sancho E, Ferrando M D, et al. Effect of an Acaricide on the Reproduction and Survival of Daphnia magna[J]. Bulletin of Environmental Contamination and Toxicology,1999,63(2):167-173.
[247]Enriquez Garcia C, Nandini S, Sarma S S S. Demographic characteristics of the copepod Acanthocyclops americanus (Sars,1863) (Copepoda:Cyclopoida) fed mixed algal (Scenedesmus acutus)-rotifer (Brachionus havanaensis) diet[J]. Hydrobiologia,2011,666(1):59-69.
[248]Sarma S S S, Martinez-Jeronimo F, Ramirez-Perez T, et al. Effect of cadmium and chromium toxicity on the demography and population growth of Brachionus calyciflorus and Brachionus patulus (Rotifera)[J]. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances & Environmental Engineering,2006,41(4):543-558.
[249]Sarma S S S, Pavon-Meza E L, Nandini S. Comparative population growth and life table demography of the rotifer Asplanchna girodi at different prey (Brachionus calyciflorus and Brachionus havanaensis) (Rotifera) densities[J]. Hydrobiologia,2003,491(1-3):309-320.
[250]Sarma S S S, Nandini S, Flores J L G. Effect of Methyl Parathion on the Population Growth of the Rotifer Brachionus patulus (O. F. Muller) under Different Algal Food (Chlorella vulgaris) Densities[J]. Ecotoxicology and Environmental Safety,2001,48(2):190-195.
[251]柯丽霞,席贻龙,查春旺,等.甲胺磷和17β-雌二醇对萼花臂尾轮虫实验种群动态的影响[J].应用生态学报,2008,19(1):157-162
[252]史清毅,汝少国,邴欣.久效磷对雄性孔雀鱼生殖毒性研究[J][J].安全与环境学报,2007,7(3):4-9.
[253]Brodkin M A, Madhoun H, Rameswaran M, et al. Atrazine is an immune disruptor in adult northern leopard frogs (Rana pipiens)[J]. Environmental Toxicology and Chemistry,2007,26(1):80-84.
[254]史清毅,汝少国,邴欣.久效磷对雄性孔雀鱼生殖毒性研究[J].安全与环境学报,2008,7(3):4-9.
[255]穆洪,张平,徐建,等.绿麦隆和阿特拉津联合染毒对小鼠睾丸的影响[J].环境与健康杂志,2007,24(1):43-44.
[256]Anderson T D, Lydy M J. Increased toxicity to invertebrates associated with a mixture of atrazine and organophosphate insecticides[J]. Environmental Toxicology and Chemistry,2002,21(7):1507-1514.
[257]高敏苓,戴树桂,张平.绿麦隆,阿特拉津单一与复合污染对蚯蚓的毒性效应研究[J].生态环境,2006,15(3):525-528.
[258]Snell T W, Hoff F H. Fertilization and male fertility in the rotifer Brachionus plicatilis. In:Rotifer Symposium IV; 1987:Springer; 1987.329-334.
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