全缘冬青幼苗（Ilex integra Thunb.）对大气O_3浓度升高的响应

采用开顶式气室（open top chambers,OTCs）装置,研究O3浓度升高（E-O3,约150μL.L-1）对常绿阔叶树种全缘冬青幼苗的影响,主要包括伤害症状、植株生长、光合色素含量、气体交换速率与叶绿素荧光、丙二醛含量以及主要抗氧化剂含量变化.经过高浓度O3处理一个生长季后,当年生全展叶片表面分布着大量的黑...     

藻华聚集的生态效应:对凤眼莲叶绿素和光合作用的影响

以凤眼莲为研究对象,模拟凤眼莲叶绿素和光合作用变化对不同蓝藻水华聚集影响的应答响应.通过深入研究藻华聚集后对水生植物的生理影响,以揭示藻华规模性暴发引起水生植物消亡的深层机制和更好地发挥植物的水体生态修复功能.结果表明,藻华聚集后2 h内溶氧会耗尽,水体中氧化还原电位值(ORP)降至-200 m V,添加60 g·L-1和120 g·L-1新鲜藻细胞的处理1、2中溶解性总氮(DTN)含量分别高达44.49 mg·L-1、111.32 mg·L-1,溶解性总磷(DTP)含量分别高达2.57mg·L-1、9.10 mg·L-1,植物根区NH+4-N含量增加至32.99 mg·L-1、51.22 mg·L-1,形成厌氧、强还原、高营养盐环境而对凤眼莲产生胁迫作用,植物叶片叶绿素浓度呈现先增加、后降低的变化趋势,处理2的叶片光合能力、气孔导度(以CO2计)则呈现快速下降,至实验结束时下降为3.95μmol·(m2·s)-1、0.088μmol·(m2·s)-1,同期对照组叶片光合能力、气孔导度分别为22μmol·(m2·s)-1、0.78μmol·(m2·s)-1,表明凤眼莲对环境胁迫有较强的光合应答响应;实验中发现处理1中老根系脱落、大量白色嫩根长出,处理2中老根系大量死亡、脱落,无白色新根长出,同时叶片发黄、枯焦开始死亡,表明在超过了凤眼莲的抗逆境能力后,就开始出现根系死亡、光合能力受到抑制,植物开始死亡,表明在藻华聚集后形成的水体生态环境恶化对凤眼莲产生重度胁迫,使植物生理功能受到抑制是导致植物死亡的主要原因之一.     

Wastewater treatment meets artificial photosynthesis: Solar to green fuel production,water remediation and carbon emission reduction

• Mitigating energy utilization and carbon emission is urgent for wastewater treatment. • MPEC integrates both solar energy storage and wastewater organics removal. • Energy self-sustaining MPEC allows to mitigate the fossil carbon emission. • MPEC is able to convert CO₂ into storable carbon fuel using renewable energy. • MPEC would inspire photoelectrochemistry by employing a novel oxidation reaction. Current wastewater treatment (WWT) is energy-intensive and leads to vast CO₂ emissions. Chinese pledge of “double carbon” target encourages a paradigm shift from fossil fuels use to renewable energy harvesting during WWT. In this context, hybrid microbial photoelectrochemical (MPEC) system integrating microbial electrochemical WWT with artificial photosynthesis (APS) emerges as a promising approach to tackle water-energy-carbon challenges simultaneously. Herein, we emphasized the significance to implement energy recovery during WWT for achieving the carbon neutrality goal. Then, we elucidated the working principle of MPEC and its advantages compared with conventional APS, and discussed its potential in fulfilling energy self-sustaining WWT, carbon capture and solar fuel production. Finally, we provided a strategy to judge the carbon profit by analysis of energy and carbon fluxes in a MPEC using several common organics in wastewater. Overall, MPEC provides an alternative of WWT approach to assist carbon-neutral goal, and simultaneously achieves solar harvesting, conversion and storage.     

稻草秸秆发酵液的抑藻效应及其机理

为有效利用农业废弃物稻草秸秆进行抑藻,本研究对不同稻草秸秆进行了特定方式的发酵,测定了发酵液对常见淡水藻类的化感效应,探讨了其中抑藻作用强的发酵液抑藻机理.结果表明：与普通稻草秸秆发酵液相比,水稻分蘖枝发酵液对铜绿微囊藻的抑制效果显著好于普通稻草秸秆发酵液（P<0.05）,作用72h水稻分蘖枝发酵液抑制率为93.21%,168h为97.96%,而稻草秸秆发酵液120h抑制率为68.20%,168h抑制率反而显著下降,只有27.65%;前者Eh₅₀为14.073h,后者为21.036h;水稻分蘖枝发酵液对蓝藻（铜绿微囊藻）和绿藻（蛋白核小球藻、斜生栅藻）3种淡水藻均有良好抑制作用,对铜绿微囊藻抑制作用最佳（P<0.05）.在水稻分蘖枝发酵液胁迫下,铜绿微囊藻叶绿素a以及藻蓝蛋白（PC）和别藻蓝蛋白（APC）含量下降,藻细胞叶绿素自发荧光值持续降低,藻细胞结构破坏.推测水稻分蘖枝发酵液的抑藻机制之一是将藻细胞光合系统作为其攻击的靶点从而抑制藻类生长,并最终破坏细胞结构,引起细胞凋亡.     

Influences of excessive Cu on photosynthesis and growth in ectomycorrhizal Pinus sylvestris seedlings

Growth and photosynthesis responses were measured for Scots pine( Pinus sylvestris L. cv. ) inoculated with ectomycorrhizal fungi ( Suillus bovinus ) under 6.5 and 25 mg/L Cu treatments to evaluate ectomycorrhizal seedlings‘ tolerance to heavy metal stress. Results showed that excessive Cu can significantly impair the growth and photosynthesis of pine seedlings, but such impairment is much smaller to the ectomycorrhizal seedlings. Under 25mg/L Cu treatment, the dry weight of ectomycorrhizal seedlings is 25% lower than the control in contrary to 53% of the non-mycorrhizal seedlings, and the fresh weight of ectomycorrhizal roots was significantly higher than those of non-mycorrhizal roots, about 25% and 42% higher at 6.5 and 25 mg/L Cu treatments respectively. Furthermore,ectomycorrhizal fungi induced remarkable difference in the growth rate and pigment content of seedlings under excessive Cu stress. At 2.5 mg/L Cu, the contents of total chlorophyll, chlorophyll-a and chlorophyll-b were 30% higher in ectomycorrhizal plants than those in non-mycorrhizal plants. O2 evolution and electron transport of PSI and PSII were restrained by elevated Cu stress. However, no significant improvement was observed in reducing the physiological restraining in ectomycorrhizal seedlings over the non-mycorrhizal ones.     

4-壬基酚对拟柱胞藻生长、抗氧化酶和光合作用的影响及机理

为探究4-壬基酚对入侵水华蓝藻拟柱胞藻的影响,对不同浓度(0.00、0.05、0.10、0.50、1.00、2.00 mg·L~(-1)) 4-壬基酚处理96 h后的拟柱胞藻叶绿素a、抗氧化酶和光合作用进行测定。结果表明,4-壬基酚对拟柱胞藻96 h半数效应浓度(96 h-EC_(50))为0.457 mg·L~(-1)。高浓度处理(0.50 mg·L~(-1))时,拟柱胞藻叶绿素a含量、最大光合效率(F_v/F_m)、光合效率(α)、最大相对电子传递速率(rE TRmax)、半饱和光强(Ik)、RC/Cs0、ET0/RC、ΦP0、ΦE0、ψ0和Sm/t(F_m)均显著下降被显著抑制,而光合系统Ⅱ中ABS/RC、DI0/RC和TR0/RC均显著增加,同时超氧化物歧化酶(SOD)、过氧化氢酶(CAT)的活性随着浓度增加明显上升。而低浓度处理下(0.10 mg·L~(-1)),拟柱胞藻的叶绿素a含量、光合效率、最大相对电子传递速率和半饱和光强增加。这些结果表明高浓度4-壬基酚处理下,拟柱胞藻的叶绿素合成受阻,光合色素减少,光合反应中心结构受损,Q-A大量累积,光合效率下降,抑制藻细胞的光合作用,导致了拟柱胞藻生长受到阻碍,而低浓度壬基酚处理下,则可能表现出低剂量毒物兴奋效应。