24%氨氯吡啶酸水剂防治林地阔叶杂草试验

选用24％氨氯吡啶酸水利，对林地一年生及多年生阔叶杂草、灌木进行防除试验。结果表明，试验剂量在1200～3600g ai／hm^2范围内时，对杂草的防效可达90％以上，对灌木防效达70％以上。该药剂对针叶用材林幼林慎用。     

浅谈工厂企业绿地景观设计——以珠海科斯特电源有限公司为例

城市化的过程离不开工业经济的发展,在新兴的城市以及在城市新兴的工业园区内,工业用地都占有极大的比重。因此,工厂企业的绿地景观与公共空间、商业空间以及其它城市空间的绿地景观一样是城市绿地景观的重要组成部分,必须引起我们的重视。作者从绿地景观设计的角度出发,结合珠海科斯特电源有限公司绿地景观设计的实例,探讨了工厂企业在绿地景观设计方面的若干问题。     

湖北襄阳市对冷冻动物产品的监管办法

通过分析湖北襄阳市实行的驻场官方兽医、冷库开办方、冷冻产品经营户三级冷冻动物产品监管模式,发现实践中存在缺乏统一性和可追溯性问题,提出了健全规章和追溯体系、统一规范标准的建议。     

应用荧光定量RT-PCR检测J亚群禽白血病病毒

针对J亚群禽白血病病毒（ALV-J）基因序列保守区域设计一对特异性引物和一条特异性探针,通过构建重组阳性标准质粒作为阳性标准品,建立了检测ALV-J核酸的荧光定量PCR方法。优化反应体系和条件后进行特异性、敏感性、重复性试验。结果显示,该检测方法特异性强,与其它禽源病毒如A亚群禽白血病病毒（ALV-A）、B亚群禽白血病病毒（ALV-B）、新城疫病毒（ NDV）、禽流感病毒（AIV）、鸡传染性贫血病毒（CIAV）和马立克病病毒（MDV）均不发生交叉反应;该方法可检测到3.2×102拷贝/μL的病毒核酸,与常规RT-PCR相比,敏感性高100倍;重复性试验的变异系数小于2%。研究结果表明,建立的Real-time RT-PCR 检测方法特异性强、灵敏度高、可重复性好,可用于ALV-J的定量检测。     

枫杨幼苗对氟离子的吸收积累规律及毒性效应

【目的】探讨枫杨幼苗对氟污染的修复潜力。【方法】以枫杨当年实生幼苗为研究对象,采用溶液培养的方法,研究不同浓度、不同 pH氟离子胁迫下枫杨幼苗的根、茎、叶的氟含量、转移系数( Tf)、生物富集系数( BCF)的变化以及对枫杨幼苗的植物毒性效应。【结果】1)随着溶液氟离子浓度的升高,枫杨幼苗根、茎、叶的氟积累量逐渐升高,当溶液氟离子浓度为10 mmol·L －1时,枫杨幼苗根、茎、叶的氟积累量最高分别为1604.60,59.41,40.80 mg·kg －1。2)枫杨幼苗体内氟含量的分布存在2种情况：当培养液氟离子浓度为0.5～5 mmol·L －1时表现为根＞叶＞茎,在氟离子浓度为10 mmol·L －1时表现为根＞茎＞叶,转移系数( Tf)介于0.029～0.125之间,可能是过高的氟离子浓度使枫杨幼苗产生了严重的生理胁迫,影响了氟离子从茎向叶的运转。3)随着处理时间的增加,各处理组枫杨幼苗的相对标准蒸腾量均呈下降趋势,溶液氟离子浓度为5,10 mmol·L －1时,对枫杨幼苗蒸腾量变化的影响显著(P＜0.05),对植物的毒性效应很强。4)枫杨幼苗根、茎、叶氟积累量在酸性环境中最大,氟转移能力也最强,在中性环境中表现一般;植物在酸性、中性环境中受到的伤害较大,植物生命活力低,而在碱性条件下时,不仅对枫杨幼苗的伤害小,而且除氟效果较好、持续性强。5)为了达到最佳的处理效果,当废水中氟离子浓度≤2.5 mmol·L －1时,可以选择在酸性条件下利用枫杨来处理;当氟离子浓度为2.5～5 mmol·L －1时,可选择在碱性条件下处理废水。【结论】枫杨幼苗积累氟的能力很强,氟转移能力独特,具有很高的耐氟性,枫杨适合于水体氟污染严重区域的水体净化和植物修复。     

Compositional analysis and preliminary toxicological evaluation of a tea polysaccharide conjugate

Tea polysaccharide conjugate is one of the main bioactive constituents of tea (Camellia sinensis L.). The chemical composition and preliminary toxicological evaluation of a tea polysaccharide conjugate was investigated to determine the possibility of using it for human consumption. Chemical analysis of tea polysaccharide conjugate showed that the tea polysaccharide conjugate was a nonstarch protein bounded acidic polysaccharide. The protein, neutral sugar, and uronic acid content of the tea polysaccharide conjugate was 3.5%, 44.2%, and 43.1%, respectively. The contents of iron, magnesium, zinc, and selenium in the tea and its polysaccharide conjugate were measured by inductively coupled plasma-optical emission spectrometry (ICP-OES). Results showed that the contents of four elements in tea polysaccharide conjugate were much higher than that of tea power. Especially, the content of iron in tea polysaccharide conjugate was increased 5.9 times. The tea polysaccharide conjugate, when fed to mice, was found to have no toxicity to the liver, kidney, heart, thymus, or spleen of the mice and none of the mice died throughout the period of the experiment. There was no significant difference between the thymus index, spleen index, and liver index of the mice from the test and control groups (P>0.05). On the basis of the study, the tea polysaccharide conjugate may be classified either as a very low toxicity substance, that is, GHS Category 5 (globally harmonized system), or as unclassified when orally administrated to mice. It might be a candidate of dietary supplements besides the bioactivities as a polysaccharide.     

Spatial and Temporal Variability in Dissolved Inorganic Nitrogen Fluxes at the Sediment–Water Interface in Lake Illawarra, Australia

In this study, benthic flux measurements of inorganic nitrogen (i.e., $ {\text{NH}}^{ + }_{4} $ , $ {\text{NO}}^{ - }_{2} $ ?+? $ {\text{NO}}^{ - }_{3} $ ) were made using a batch incubation system at different stations (i.e., shallow sandy macrophyte and unvegetated beds, and deep central mud) over four seasons in Lake Illawarra, NSW, Australia, to study the influence of different primary producers (i.e., seagrasses, microphytobenthos (MPB) and macroalgae) and/or different sediment types (i.e., sand or mud) on the benthic fluxes. In general, nutrient fluxes displayed typical diel variations, with lower flux out of sediments (release) or enhanced uptake by the sediment in the light, due to the photosynthetic activities of the plant-MPB-sediment community in Lake Illawarra during photosynthetic periods. A distinct seasonal pattern of inorganic-N fluxes was also observed (e.g., the marked difference between summers 2002 and 2003). This may be explained by the seasonal variations in the biomass and activity (growing or decay phases) of MPB, seagrass and macroalgae, which may influence their nutrient assimilation and alter the chemical conditions of surface sediments that influence the benthic geochemical processes and thus benthic nutrient fluxes. On an annual basis, unvegetated sediments displayed net DIN effluxes, while seagrass beds showed a net DIN uptake, and the highest DIN uptakes coincided with the largest standing crop of seagrass and/or macroalgae and the highest levels of benthic community production. This may be due to the enhanced denitrification and/or assimilation activity by rooted plants and macroalgae, and the effect is most efficient during periods of net growth (e.g., in Spring 2002).     

巴东皱皮木瓜发育及主要成分的变化分析

以湖北巴东产的皱皮木瓜为试验材料,分别在皱皮木瓜果实7个不同生长期采样,通过果实颜色、纵横径、鲜果质量等形态特征的测定,并采用HPLC法对不同生长期内的有效成分(齐墩果酸、熊果酸、原儿茶酸、绿原酸)进行检测,综合评价皱皮木瓜最佳的采收季节和质量指标。结果表明:(1)皱皮木瓜的纵径、横径、鲜果质量增长随生长阶段呈逐渐递增趋势;(2)在不同生长期有效成分含量呈上升或者下降的趋势。其中,齐墩果酸和熊果酸含量在整个发育过程中逐渐增加,7月10日—20日增加较为明显,两者在成熟期达到最大值,原儿茶酸和绿原酸在幼果期时保持较高的含量,两者变化趋势为降—升—降。     

抚育间伐对小兴安岭天然针阔混交林碳储量的影响

在小兴安岭地区带岭林业实验局东方红林场天然林试验区,设置6块样地,对天然针阔混交次生林进行不同强度(10%、15%、20%、25%、30%、35%)的抚育间伐;采用平均标准木法取样、实验室重铬酸钾法测定林木碳质量分数,分析不同间伐强度对乔木层地上部分生物量及碳储量的影响。结果表明:随着间伐强度的增加,乔木层地上部分生物量、碳储量整体呈先增加再减小趋势,但间伐8 a内各间伐生物量、碳储量均显著少于对照。伐后1~4 a,间伐强度20%,乔木层碳储量增长率、增长量均高于对照;间伐后1~4 a内,间伐强度20%,乔木层碳储量的恢复能力最强。间伐后5~8 a,高度间伐(间伐强度30%、35%)碳储量恢复能力最弱;间伐8 a后,各间伐强度(10%、15%、20%、25%、30%、35%)的碳储量,分别为74.93±3.42、86.96±7.31、99.24±2.43、93.64±6.68、85.23±2.11、79.54±3.38 t/hm2,林木各器官碳储量差异显著,从大到小依次为树干、树枝、树叶;间伐8 a后,各间伐树干碳储量所占比例比对照所占比例增加-0.04%~12.27%,在间伐强度为20%时树干碳储量比例最高,说明间伐强度20%有利于小兴安岭天然针阔混交林树干碳储量的累积及单株林木质量的提高。总体看,短期间伐(4 a内)利于20%间伐乔木层碳储量的迅速积累,8 a内各间伐仍处于乔木层地上部分碳储量低于对照的恢复期。