印度Leh地区沙棘籽油中脂肪酸测定

本文分析了印度Leh地区沙棘籽油中脂肪酸各成分的含量,结果显示沙棘种子含油量为17.61%,籽油富含油酸(23.012%)和亚油酸(30.162%).     

三种滴灌肥对草莓生长、产量及品质的影响

为了研究滴施氨基酸、全生物有机肥和黄腐酸复合肥对草莓生长、产量及品质的影响.在克拉玛依白碱滩区设常规对照处理基础上,追施氨基酸、全生物有机肥和黄腐酸复合肥3种有机肥,共4个处理,3次重复,随机排列,分析3种滴灌肥与草莓特性之间的关系.结果表明:3种滴灌肥能够显著提高草莓株高、单株叶面积和全株生物量,成熟期分别提高18....     

115份贵州茶树资源氨基酸和茶氨酸分析与特异资源筛选

为筛选高氨基酸和高茶氨酸茶树资源,探明贵州茶树资源氨基酸和茶氨酸特性,本研究分别利用分光光度法和高效液相色谱法测定115份贵州地方茶树资源春季一芽二叶生化样的氨基酸总量和茶氨酸含量。结果表明：115份茶树资源的氨基酸总量在0.95%～7.96%,平均值为3.40%;茶氨酸含量在0～3.80%,平均值为1.58%;茶氨酸占比在0～67.66%,且集中分布于40%～<60%。在这115份茶树资源中,发现特异高氨基酸(氨基酸总量≥5%)茶树资源11份、特异高茶氨酸(茶氨酸含量≥3%)茶树资源3份。不同地方的茶树资源,其氨基酸总量和茶氨酸含量存在较大差异,其中,贵定、黎平和石阡的茶树资源表现出较高的氨基酸总量和茶氨酸含量,而三都和普安的茶树资源氨基酸总量和茶氨酸含量显著(P<0.05)低于其他地方。来自三都的突肋茶(Camellia costata)资源表现出更原始的生化性状,均未检测出茶氨酸。聚类分析结果显示,115份茶树资源可分为5类,其中,石苔14号以远高于其他资源的氨基酸总量和茶氨酸含量单独分为一类。     

表层土壤中菲的紫外光降解研究

多环芳烃化合物（PAHs）由于致癌、致畸和致突变而受到广泛关注。本实验以多环芳烃菲（Phe）为目标污染物,研究了温度、腐植酸和紫外辐射强度对Phe光降解的影响并对不同因素对降解动力学的影响作了研究。结果表明,Phe的降解在20 ℃到30 ℃范围内,随着温度的升高,光降解率增加;腐植酸在Phe污染土壤的光降解中起敏化作用,可显著促进光解,腐植酸浓度为5 mg·kg^-1足以达到敏化的效果;Phe光降解速率常数随辐射强度的降低而降低,呈正相关,光解的半衰期随着辐射强度的降低而增加,呈负相关。     

有机酸对液培玉米吸收137Cs和90Sr的影响

利用液培方法研究胡敏酸钠等有机酸盐作用下玉米幼苗对放射性核元素137Cs和90Sr的吸收速率。研究结果表明:利用有机酸盐可以降低玉米幼苗对放射性核元素的吸收速率。1低活度放射性核素水平下,对照(不加有机酸盐)的玉米幼苗中发现了97%放射性核元素137Cs,而高活度放射性核素水平中为61%;有机酸盐不同程度地降低了玉米幼苗中放射性核元素137Cs的量。在低活度水平中四苯硼钠降低137Cs的量最多, 玉米仅吸收12%,而酒石酸钾钠处理中玉米吸收量最高,为45.5%。对137Cs的吸收率,在胡敏酸钠处理中为23.9%, EDTA-Na处理中为41.3%;在高活度放射性核素水平中吸收率的顺序为四苯硼钠11%,胡敏酸钠26%,酒石酸钾钠28.7%,EDTA-Na 37%。2低活度水平下,对照中放射性核元素90Sr的56%被玉米幼苗吸收,而高活度水平中达61%。有机酸盐在低活度水平中降低放射性核元素90Sr的顺序为胡敏酸钠 23.9%,EDTA-Na 26%,酒石酸钾钠28%和四苯硼钠36%;在高活度水平中为四苯硼钠11%,EDTA-Na 24%,胡敏酸钠26%,酒石酸钾钠 31%。3低活度和高活度水平中,四苯硼钠和胡敏酸钠降低玉米幼苗体内的放射性核元素性质为最佳。4所有有机酸盐处理与对照之间的差异都达到极显著水平。     

养分缺乏下外源有机酸对暗棕壤磷有效性及落叶松幼苗吸收积累磷的影响

用不同比例A1和B层暗棕壤混合(A1∶B=1∶2)制造土壤养分缺乏条件,栽植落叶松幼苗,通过模拟我国东北林区代表性森林凋落物淋洗液中有机酸的种类和数量,系统研究养分缺乏下,不同浓度外源有机酸对暗棕壤磷有效性和落叶松幼苗吸收、运输磷素养分的影响及机理,以探讨利用有机酸提高养分缺乏下落叶松幼苗抗土壤贫瘠能力的可行性及机制。结果表明,A1层与B层混合土壤速效磷含量降低,落叶松幼苗根系和叶片磷累积量和磷吸收效率降低,但磷利用效率增加。外源有机酸处理后,混合土壤的速效磷含量有不同程度提高,3种有机酸的作用强弱表现为琥珀酸>柠檬酸>草酸,一般以浓度5.0mmol/L和处理20d时提高效果最显著。有机酸不同程度提高了根系和叶片的磷累积量和磷吸收效率,但降低了磷利用效率。有机酸对磷累积量和磷吸收效率的提高程度因处理时间、有机酸浓度和种类而异:对于根系,20d和30d的结果高于10d,叶片则为10d和20d的结果高于30d,说明处理前期磷被吸收后向叶片的转移量较多,而后期则更多地在根中积累;3种有机酸大多在浓度为10.0mmol/L时提高幅度最大;不同有机酸的促进程度为琥珀酸>柠檬酸>草酸。因此,外源有机酸能通过提高落叶松幼苗对养分缺乏土壤中磷的吸收能力,促进磷的积累,进而提高苗木对养分缺乏土壤的耐性和适应能力。     

土壤微生物群落结构对凋落物组成变化的响应

凋落物分解是陆地生态系统养分循环的关键过程,明确凋落物多样性如何影响土壤微生物群落构成和多度,继而潜在地改变凋落物分解的微生物学机制有助于认识生物多样性和森林生态系统功能的关系。通过小盆模拟试验,应用磷脂脂肪酸谱图的方法研究了我国南方红壤丘陵区典型物种马尾松和湿地松的凋落物分别与白栎和青冈的凋落物混合,与单一针叶凋落物分解时相比,针阔混合凋落物分解过程中土壤微生物群落结构的变化,结果显示:(1)针阔混合凋落物分解时土壤微生物群落磷脂脂肪酸(Phospholipidfatty acids,PLFA)总量低于单一针叶处理,细菌和放线菌的相对多度高于单一针叶处理,真菌则相反,群落真菌/细菌低于单一针叶处理,土壤微生物生物量的差异主要来自于真菌;(2)主成分分析表明:针阔混合凋落物分解与单一针叶凋落物分解的土壤微生物群落结构差异显著,两个时期(分解9个月和18个月)主成分一分别可以解释65.74%和89.63%的变异,第一主成分主要包括18∶2ω6,9、18∶1ω9c、17∶0和10Me18∶0等磷脂脂肪酸;(3)土壤微生物群落结构受凋落物初始C/N和木质素/N调控,土壤微生物群落细菌的相对多度与凋落物初始C/N和木质素/N显著负相关,真菌则与凋落物初始C/N和木质素/N显著正相关,群落真菌/细菌与凋落物初始C/N和木质素/N显著正相关。针阔凋落物混合分解通过改变凋落物C/N和木质素/N,提供了对分解者更为有利的微环境。     

Interaction of arbuscular mycorrhizal fungi and rhizobia: Effects on flax yield in spoil‐bank clay

This study focused on the application of native strains of arbuscular mycorrhizal fungi (AMF) and Sinorhizobium in effective crop production during reclamation of coal‐mine spoil banks. Two greenhouse experiments were conducted in spoil‐bank clay with a low dose of organic amendment to determine whether the microbial inoculation improves growth and utility qualities of two cultivars of Linum usitatissimum L. (oil and fiber flax). Inoculation with two native AMF isolates (Glomus mosseae, G. intraradices, and their mixture) significantly increased growth and shoot phosphorus (P) concentration of both flax cultivars. Inoculated fiber flax plants produced fivefold more fibers than the uninoculated ones. In oil flax, mycorrhizal inoculation significantly but quantitatively to a minor degree decreased the concentration of nonsaturated fatty acids in the seed oil. A mixture of five native Sinorhizobium sp. strains supported growth and P uptake of oil flax only in the absence of AMF. However, these beneficial effects of the bacteria were significantly lower as compared to AMF. No synergic action of Sinorhizobium strains and AMF was observed, and their interactions were often even antagonistic. Inoculation with AMF significantly decreased population density of Sinorhizobium in the soil. These results suggest that a careful selection of suitable bacterial strains is necessary to provide effective AMF combinations and maximize flax‐growth support.     

Effects of Irrigation Patterns and Nitrogen Fertilization on Rice Yield and Microbial Community Structure in Paddy Soil

Water and nitrogen (N) are considered the most important factors affecting rice production and play vital roles in regulating soil microbial biomass, activity, and community. The effects of irrigation patterns and N fertilizer levels on the soil microbial community structure and yield of paddy rice were investigated in a pot experiment. The experiment was designed with four N levels of 0 (N0), 126 (N1), 157.5 (N2), and 210 kg N ha-1 (N3) under two irrigation patterns of continuous water-logging irrigation (WLI) and water-controlled irrigation (WCI). Phospholipid fatty acid (PLFA) analysis was conducted to track the dynamics of soil microbial communities at tillering, grain-filling, and maturity stages. The results showed that the maximums of grain yield, above-ground biomass, and total N uptake were all obtained in the N2 treatment under WCI. Similar variations in total PLFAs, as well as bacterial and fungal PLFAs, were found, with an increase from the tillering to the grain-filling stage and a decrease at the maturity stage except for actinomycetic PLFAs, which decreased continuously from the tillering to the maturity stage. A shift in composition of the microbial community at different stages of the plant growth was indicated by principal component analysis (PCA), in which the samples at the vegetative stage (tillering stage) were separated from those at the reproductive stage (grain-filling and maturity stages). Soil microbial biomass, measured as total PLFAs, was significantly higher under WCI than that under WLI mainly at the grain-filling stage, whereas the fungal PLFAs detected under WCI were significantly higher than those under WLI at the tillering, grain-filling, and maturity stages. The application of N fertilizer also significantly increased soil microbial biomass and the main microbial groups both under WLI and WCI conditions. The proper combination of irrigation management and N fertilizer level in this study was the N2 (157.5 kg N ha-1) treatment under the water-controlled irrigation pattern.     

Effect of salinity on nitrogen metabolism in wheat

Objectives of our studies were to quantify effects of salinity on growth and nitrogen metabolism of wheat and to measure variation in response of different cultivars, hybrids, and classes. Methods and criteria for identifying resistance to salinity in wheat, particularly effects on nitrogen metabolism also were tested. Variation in response to salinity was measured by subjecting seedlings of six wheats to one control treatment (‐0.1 bars) and two stress treatments (‐3.5 and ‐10.4 bars) from NaCl, MgSO₄, and MgCl₂ in hydroponic solutions. Both stress treatments retarded growth; wheats significantly varied at ‐3.5 bars but not at ‐10.4 bars. Stress decreased root and shoot nitrate N and total N contents. Studies with one wheat cultivar showed that salinity decreased activity of nitrate reductase enzyme and stimulated accumulation of proline. Salinity more adversely affected vegetative stages than reproductive stages of plants grown to maturity. We concluded that salinity affected wheat by both osmotic effects and antagonism of nitrate metabolism from chloride. Absolute growth and relative growth at different stress levels were superior to differences in nitrogen metabolism as selection criteria for salinity tolerance.