红花对土壤矿质元素的吸收和积累

采用电感耦合等离子体原子发射光谱法(ICP-AES)检测红花不同部位和时期以及栽培土壤中K、Ca、Na、Mg、Fe、Cu、Zn、Mn、Cr、Cd、Pb、Ba、Ni和Al元素的含量。结果表明:红花各部位矿质元素含量差异明显。在红花各不同部位中K、Fe、Zn元素在幼苗中含量最高,Ca、Mg元素在成熟叶中含量最高,Cu元素在种子中含量最高;而K和Ca元素在种子中含量最低,Mg、Fe、Cu和Zn元素分别在花、茎、成熟叶和茎中含量最低。红花的幼苗和花对K元素吸收积累明显,幼苗和种子对Cu元素吸收积累明显,Ca元素在成熟叶中积累较多,相应元素含量远比土壤中相应的元素含量高。红花对土壤不同矿质元素的吸收利用差异较大,在长期栽培红花的土壤中应注意对吸收利用多的元素结合施肥进行补充。     

珍稀濒危植物矮牡丹体内矿质元素的研究

采用原子吸收分光光度法测定了矮牡丹体内的10种矿质元素,即K、Mg、Mn、Fe、Ni、Zn、Cu、Cd、Cr、Pb。分析了矿质元素在矮牡丹体内的分布规律及矮牡丹对各种元素的富集能力。结果表明:在不同器官中的矿质元素含量有显著差异, K、Mg、Mn、Ni、Cd、Cr、Pb以叶中为高, Fe、Zn、Cu分别以根、茎、叶柄中含量最高;大多数元素在叶柄中含量最低。矮牡丹对K、Mg、Mn、Fe、Zn有较强的吸收富集能力,一般叶的富集系数较其它器官为高。元素间相关分析表明:Zn、Cd、Cr、Pb、Mn、Fe、Ni、Cu之间有显著的相关性, K、Mg之间的相关性显著。此外,土壤与植物体内元素含量表现出显著的相关性。     

镉胁迫下草莓幼龄期叶、根矿质元素积累和分布的变化

采用水培实验,研究重金属镉对草莓幼龄期叶、根矿质元素含量和分布的影响。结果表明,高量镉降低草莓根中K、Ca、Mg、P、Cu、Zn、Mn、Fe的积累,叶片相应元素以及B、Mo含量也随镉浓度增大而呈降低趋势;但镉浓度较低时,K、Mg、P、Zn在叶、根中的含量均增加,而后才随镉处理浓度提高而降低。在镉胁迫下,同一元素在草莓叶、根之间的分布也受到影响,而且某些矿质元素含量间有显著相关性。     

小麦籽粒不同部位的矿质元素组成与其含量差异

采用X-射线能谱仪测定非糯与糯性等品种小麦籽粒不同部位的矿质元素组成(H和He元素除外)和含量的结果表明:小麦籽粒中除含有大量C、O外,皮层富含K、P、se,其次是Cl、Si、S、Mg和Ca等;糊粉层富含P、K和Mg,其次是Si、Se、S、Ca、Cl和Fe等;胚乳层中相应的矿质元素含量比皮层和糊粉层低。不同品种籽粒各部位的矿质元素含量存在遗传性差异。据此认为籽粒磨成粉时应减少糊粉层的损失,以提高面粉的矿质价值。     

增温对长白山苔原植物叶片和土壤矿质元素含量的影响

温度变化会影响植物对养分的吸收以及自身养分含量变化,尤其对长期处于低温条件下的苔原植物。采用开顶箱增温法,研究了1个生长季增温对长白山苔原3种代表植物——牛皮杜鹃(Rhododendron aureum Pall)、笃斯越桔(Vaccinium uliginosum)和东亚仙女木(Dryas octopetala var.asiatica)叶片及土壤矿质元素钾(K)、铝(Al)、铜(Cu)、铁(Fe)、镁(Mg)、锰(Mn)、锌(Zn)和钙(Ga)含量的影响。结果表明:1)增温明显改变了土壤矿质元素含量,使土壤Fe、Al和K含量分别增加0.44%、2.76%和4.88%,而Cu、Mg、Mn、Zn和Ga含量分别降低2.63%、5.07%、7.46%、21.95%和15.60%;2)整个生长季,增温使牛皮杜鹃叶K含量增加8.17%,且具有明显的月变化,其叶Mg和Mn含量也分别比对照组高66.39%和14.73%;3)与对照相比,增温使笃斯越桔叶K、Al和Zn含量分别增加15.24%、5.45%和87.45%,生长季不同月份,其叶K、Al、Mg、Mn、Zn和Ga含量差异明显;4)增温并没有明显改变东亚仙女木叶片各矿质元素含量,但其叶K、Cu和Ga含量具有明显月波动。因此,不同物种矿质元素含量变化对增温的响应方式不同,增温对苔原植物的影响也存在一定的物种差异性。     

新疆绿洲农田土壤-棉花系统9种矿质元素生物循环特征

在新疆绿洲区,对不同连作棉田土壤中9种矿质元素含量、棉花植株的吸收和富集特性以及棉田养分收支量等进行分析,研究了农田土壤-棉花系统矿质元素的生物循环特征。结果表明:棉田土壤中微量元素和大量元素均有一定程度的贫化趋势,以Mo的耗竭最为严重。棉株不同器官累积矿质元素的能力有明显差异,叶片中Ca、Mg和Mn的含量较高,根、茎中K、Na、Fe、Mo含量较高,棉籽中Zn和Cu含量最高;不同产品器官对矿质元素的吸收和富集能力不同,秸秆为:MoKMgCaCuZnNaMnFe,纤维:MoKMgZnCuCaNaMnFe,棉籽:MoZnKMgCuCaMnNaFe。棉花对Mo的吸收能力最强,长期连作导致土壤中Mo耗竭较为严重;随籽棉的收获,从棉田移出Zn、Cu的比例和数量较高,大量元素中移出Mg、K较多;棉花对Mn、Fe、Ca、Na的吸收量虽然较多,然而大部分富集在秸秆中,随着棉花秸秆的还田作用,将归还于耕作层并有大量富集,消耗量不大。新疆棉花长期单一种植,应重点补充Mo、Zn和Cu微量元素肥料,酌情补充Mg、K等大量元素肥料。棉田Ca、Na含量较新疆土壤背景低,预示着棉田土壤在向着脱盐碱方向发展,然而两元素在秸秆中的比例较高,因此棉花长期连作农田,应注意防止耕作层土壤向次生盐碱化方向发展。     

江苏东山山地枇杷果实品质与果园土壤、叶片和果实矿质元素的关系

以江苏省苏州吴中区山地种植的24个枇杷果园的‘白玉’枇杷为研究对象,采用典型相关分析法研究土壤、叶片和果实矿质元素间及其与果实品质指标的相关性,应用多元线性回归分析法筛选影响枇杷果实品质的土壤、叶片和果实的主要矿质元素和影响叶片矿质元素的主要土壤矿质养分因子,为改善枇杷果实品质的果园营养管理技术提供理论参考依据。结果表明:(1)枇杷果实品质指标在不同果园间存在较大差异。(2)枇杷果实品质主要受其叶片和果实矿质元素含量影响,其中:枇杷单果质量与叶片中N含量呈显著正相关,与果实中N含量呈显著负相关;可溶性固形物含量与叶片中N和Mg元素含量呈极显著正相关,与果实中P、Mn元素含量呈极显著正相关,与果实中Ca、Mg元素含量呈极显著负相关;可滴定酸含量与叶片中N和Zn元素含量呈显著负相关,与果实中N、Mn元素含量呈显著负相关,与果实中Ca元素含量呈显著正相关。(3)果实品质指标与土壤矿质养分含量的相关性较弱,土壤矿质养分主要通过影响叶片矿质元素含量,进而间接影响果实品质,其中土壤中P、K、Ca、Mn、Cu元素对叶片中矿质元素含量影响较大。研究认为,提高土壤中P、K、Zn含量并减少土壤Ca含量是东山山地枇杷果园土壤管理的关键技术途径;提高叶片中N含量以及果实中N、P、Mn含量和减少果实中Ca、Mg含量是改善东山山地枇杷果实品质的关键措施。     

江苏海岸带陆生盐土植物矿质元素含量的特点及生物循环

陆生盐土植物在生长过程中吸收积累了大量的Cl和Na;从海向陆随着土壤和植被的生态演替,植物中Cl和Na的浓度逐渐降低;N与Cl、Na有相似的水平分布规律;植物种类是影响元素吸收积累的主要因素。在盐地碱蓬中N、P、K、Ca、Mg、Na、Cl、Mn和Zn的含量均是生长前期较高,随着其生长老化逐渐降低,大穗结缕草、白茅与盐地碱蓬相比,Ca的含量前期低后期高,Na、Mn、Cu和Zn的季节变化不明显。参加盐地碱蓬系统生物循环的元素中,Cl和Na的比例最大,在大穗结缕草和白茅生态系统中比例较小;由于白茅被收割利用,一些元素从此生态系统中流失。     

霍山石斛组培苗移栽后微观结构与微区元素的变化研究

采用扫描电镜及X射线能谱仪技术,研究霍山石斛组培苗移栽后各器官组织的微观结构和所含元素的变化,以了解霍山石斛组培苗生长发育以及药效成分的状况。结果表明:(1)霍山石斛组培苗移栽2个月后,根增粗近1倍,具有根被,且根被细胞壁的网络状增厚更加明显,表皮、皮层、中柱发育分化更加完善,Mg、Si、Cl、S、K、Ca元素含量提高,其中Ca增长了2.76倍。(2)茎表面纵向凹陷增多,内部结构致密,维管束发育较为完善,细胞内充满物质,Mg、Si、Cl、S、K、Ca、Fe、Cu、Zn元素含量增多,尤其是K和Fe分别增长了3.25倍和4.61倍。(3)叶增厚,具有了角质层,气孔形状更加饱满,叶肉细胞内含物丰富,Mg、Si、Cl、S、K、Ca、Fe、Mn、Zn的含量显著上升,其中K升高了17倍。(4)与根、叶相比,茎中所富集的元素种类最多。研究认为,霍山石斛试管苗移栽后,生长发育趋向完善,各项功能增强,细胞内含物质增多,元素成分丰富并且含量提高,体现出对移栽环境的良好适应性。     

铜处理对菠菜幼苗矿质营养吸收和细胞超微结构的影响

土壤重金属积累严重影响植物生长和生态系统平衡,探寻植物对重金属的耐性机理尤为重要.菠菜可能具有一定的耐铜性,但Cu对其矿质元素吸收、细胞超微结构等方面的耐性机理尚不明确.本研究以菠菜幼苗为研究对象,通过盆栽试验,探究不同浓度铜处理对菠菜幼苗生长、矿质元素吸收、叶片细胞超微结构等指标的影响.结果表明: 100 mg·L^-1 CuSO₄处理浓度时,菠菜幼苗根Cu²⁺积累量小于地上部,其根系生长量增加,地上部生长量稍有下降,继续增加铜处理浓度,植物体各器官生长参数均呈下降趋势.低浓度铜处理时(<400 mg·L^-1 CuSO₄),菠菜幼苗叶N、K、Ca、Mg、Fe含量增加,P含量减少;根N、P、K含量减少,Ca、Mg、Fe含量增加;叶片细胞内各细胞器清晰可见,基粒片层排列仍较为整齐,叶绿体内外膜完整.高浓度铜处理时(>600 mg·L^-1 CuSO₄),菠菜幼苗叶N含量增加,P、K、Ca、Mg、Fe含量减少;根N、P、K、Ca、Mg、Fe含量均减少;叶片细胞内叶绿体变圆,叶绿体膜变薄,基质、基粒片层变少,层堆积高度下降,细胞核解体,液泡、细胞壁中有黑色小点分布,可能是大量Cu²⁺聚集导致细胞内膨压增大所致.低浓度铜处理并未对菠菜幼苗的生长生理特性产生明显的负面影响,而高浓度铜处理并未终止菠菜幼苗的生长.说明菠菜幼苗具有一定的耐铜性.     

秦岭产9种野菜中矿质元素含量的比较

野生蔬菜是指自然生长且未经人工栽培的蔬菜,因其富含人体所需的矿质元素、氨基酸及多种维生素而备受人们青睐[1-3],被公认为天然绿色食品.近年来,随生活水平的提高,多样化的饮食结构驱使人们不断对各种食品进行开发,尤其在旅游业的发展带动下,食用野菜已成为一种时尚和保健的需要.     

Effect of dietary Ca and Cd level of pregnant rats on reproduction and on dam and progeny tissue mineral concentrations.

Pregnant Sprague-Dawley rats were used to determine the effects of the addition of 200 ppm of Cd (as CdCl2) to the diet factorially with two levels of dietary Ca (0.07% and 0.96%) on reproductive performance, concentrations of Cd, Cu, Fe, Zn, Ca and Mg in dam liver and kidney and in newborn progeny. High Cd significantly increased liver and kidney Cd, Zn and Ca and decreased liver Fe. High dietary Ca partially protected against accumulation of Cd in liver and kidney but had no effect on concentration of other elements. Number of live or stillborn pups per litter was not significantly affected by diet but high Cd significantly reduced pup birth weight. No grossly abnormal pups were noted. Concentration of Cd in bodies of newborn pups was increased approximately 8.6-fold by high Cd in the diet of dams fed the 0.07% Ca-diet and 3.8-fold by high-Cd in the diet of dams fed the 0.96% Ca diet. Pup, Zn, Cu and Fe contents were significantly decreased and Ca was significantly increased by high-Cd in the maternal diet whereas pup Mg content was unchanged. Maternal Ca intake had no effect on concentration of Zn, Cu, Fe or Ca in newborn pups. The biological importance of the alteration in maternal and fetal tissue concentration of Zn, Cu and Fe by high-Cd maternal diets is unknown.     

Growth and Nutrient Uptake by Barley (Hordeum vulgare L. cv Herta): Studies Using an N-(2-Hydroxyethyl)ethylenedinitrilotriacetic Acid-Buffered Nutrient Solution Technique (I. Zinc Ion Requirements)

The critical range of Zn2+ activity in nutrient solution required for optimum growth of barley (Hordeum vulgare L. cv Herta) was studied using the synthetic chelating agent N-(2-hydroxyethyl)ethylenedinitrilotriacetic acid to buffer micronutrient metal ions. The activity of Zn2+ was varied over a wide range from approximately 0.1 x 10-11 to 22 x 10-11 M Zn2+. The dry weight of barley shoots reached a maximum at Zn2+ activities above approximately 3 x 10-11 M and was clearly depressed when Zn2+ activities were below about 1 x 10-11 M. The relationship in shoots between dry weight and Zn concentrations supports the view that there is a critical Zn concentration of about 25 [mu]g g-1 dry weight in whole shoots of barley seedlings. When Zn2+ activities in solution were near or below approximately 3 x 10-11 M, barley shoots accumulated higher concentrations of P, Mn, Ca, Mg, and Na, whereas Cu concentrations were reduced. P and Mn began to accumulate in the shoots before differences in dry weights were apparent and provided the earliest index of Zn deficiency. In Zn-deficient roots, concentrations of Ca and Mg increased by 25 to 30%, and those of Fe and Mn more than doubled. Zn appears to play a special role in regulating uptake of several mineral nutrients in barley.     

Longitudinal monitoring of selected elements in blood of healthy young children

There are limited data on essential nutrients in the whole blood of young children. As part of a longitudinal study of the impact on young children and the environment from the introduction of an organic Mn compound into unleaded gasoline in Australia, we have measured a suite of elements in whole blood. The children, aged between 6 and 31 months at recruitment, have been monitored at 6-month intervals for up to 5 years. Blood samples were analysed by inductively coupled plasma mass spectrometry for Ca, Mg, Fe, Mn, Cu, Zn and Pb. Mixed model analyses of 665 blood samples using backward elimination showed significant positive relationships between Ca, Mg and Zn and season, variable relationships with time, but no association with gender or traffic exposure. The elements Ca, Mg and Zn showed higher concentrations in summer compared with winter, whereas Fe and Pb showed lower concentrations in summer compared with winter. Concentrations of all elements except Fe showed significant effects over time: Ca, Cu, Mg, Pb and Mn showed decreases over time, whereas Zn showed an increase. The mixed model analyses with the individual elements as the dependent variable showed some interesting relationships and require further follow-up as some of these appear to conflict with pre-existing concepts, although the multi-element data on which these concepts are based are limited. The variance for blood Pb and blood Mn arising from the other elements was small with 0.5% in the case of blood Pb and 3.7% for blood Mn.     

Room temperature solvent extraction for simple and fast determination of total concentration of Ca,Cu, Fe,Mg, Mn,and Zn in bee pollen by FAAS along with assessment of the bioaccessible fraction of these elements using in vitro gastrointestinal digestion

Background and aimBee pollen is recognized to be a source of different nutrients, including minerals. As a food supplement, its quality and safety due to concentrations of essential macro- and microelements, and harmful trace elements has to be verified. Fast and simple element analysis of bee-collected pollen can be regarded as an important part of its quality assurance and control. The present study aimed at developping a new method for determination of selected elements (Ca, Cu, Fe, Mg, Mn, Zn) of bee pollen based on solvent extraction and completely avoiding a high temperature treatment with concentrated reagents. In addition, in vitro gastrointestinal digestion was used to assess bioavailability of elements from this food supplement.MethodsBee pollen samples were dried and pulverized. Total concentrations of Ca, Cu, Fe, Mg, Mn, and Zn were determined by flame atomic absorption spectrometry (FAAS) in sample solutions obtained by wet digestion (WD) in concentrated HNO₃ or alternatively by solvent extraction (SE) with diluted solutions of HNO₃. Gastrointestinal digestion was mimicked using simulated solutions of gastric and intestinal juices followed by determination of Ca, Cu, Fe, Mg, Mn and Zn concentrations in the bioaccessible fraction by FAAS.ResultsA new simple and fast method for determination of total concentrations of Ca, Cu, Fe, Mg, Mn, and Zn in bee pollen was developed and validated. The method combined room temperature, two-hour SE with 0.5 mol L⁻¹ HNO₃ with FAAS measurements versus simple standard solutions. It provided precision within 1–5 % and trueness better than 8%, and was shown to be suitable for fast analysis of different polyfloral bee pollens. In vitro gastrointestinal digestion revealed that elements were well (70–85 % for Ca, Mg) and fairly (27–43 % for Cu, Fe, Mn, and Zn) bioaccessible from bee pollen. By pouring with water and swelling overnight, bioaccessibility of studied elements from such prepared bee pollen was increased on average by less than 15 % (Mn), 20 % (Ca, Cu, Fe, Zn) or 30 % (Mn).ConclusionsAvoiding long-lasting, high-temperature wet digestion with concentrated reagents, the proposed sample treatment along with FAAS provided precise and true results of total concentrations of Ca, Cu, Fe, Mg, Mn, and Zn in bee pollen. The method was simple and fast, and enabled to analyze a higher number of samples. Simulated gastrointestinal digestion of bee pollen have shown for the first time that Ca and Mg are the most bioaccessible from this bee product. Bioaccessibility of Cu, Fe, Mg, and Zn from bee pollen are close to or lower than 40 %.     

Effect of trace elements on surface hydrophobicity and adherence of Escherichia coli to uroepithelial cells

Trace elements have significant effect on the physiology of bacteria. Variation in the concentration of trace elements may affect the expression of virulence by microorganisms. The effect of trace elements on hydrophobicity and adherence of E.coli to uroepithelial cells was studied. Increasing concentrations of Ca2+, Mg2+, Fe3+ and Zn2+ significantly decreased the surface hydrophobicity. Toxic trace elements like Co2+, Cu2+, Mn2+ and Ni2+ did not alter surface hydrophobicity. With regards to adherence of E.coli to uroepithelial cells, only Mg2+ had significant effect. Toxic trace elements decreased the rate of cell adherence. The pathogenic strains of E.coli showed higher surface hydrophobicity and better cell adherence compared to the nonpathogenic strains. There was good correlation between surface hydrophobicity and cell adherence at higher concentrations (0.1 to 0.2mM) of Fe2+ and Zn2+. The results indicated that trace elements can significantly affect surface hydrophobicity and adherence of E.coli to uroepithelial cells. Such effect may have a significant impact on the initial stages of bacterial infection.     

Effects of aluminum and deferoxamine on concentration of essential elements in animals experimentally intoxicated with aluminum]

To assess the effect of aluminium intoxication in tissues of experimental animals on Ca, Mg, Zn, Cu, and Fe concentration, aluminium nitrate was administered intraperitoneally to mice at a daily dose of 0.27 mMol/kg for 5 weeks. Concentration of Al, Ca, Mg, Zn, Cu, and Fe were analyzed by atomic absorption spectrometry. The Al content in liver and tibia was significantly higher in treated mice in comparison with control group. In Al loaded tissues the significant increase of all tested essential elements was found. To evaluate the results of DFO treatment on essential elements, mice received 6 times intraperitoneally 3.5 mMol/kg of DFO. This treatment had generally no effect on reduction of Al concentration in tibia and liver, as well as on changes in essential elements concentration.     

Particle size and metal distributions in anaerobically digested pig slurry

Particle size distribution and trace element patterns were studied in a full-scale anaerobic digestion plant treating pig slurry. Mass balance was established for major (N, P, K, Ca, Fe, Mg and S) and minor (Al, Cu, Mn and Zn) elements. Most of the elements were conserved through the process but part of the P, Ca, Mg and Mn was deposited as crystals lining the digester. In the dry matter of the slurry, Cu and Zn occurred at between 170 and 2600 mg kg(-1) due to pig diet supplements. Analyses of particle size distributions in raw and digested slurries showed a general shift in distribution towards larger sizes due to degradation of small and easily degradable particles as well as formation of large microbial filaments. Graded sieving of digested slurry showed metals to be mainly present on 3-25 microm particles. Less than 2% Cu and Zn was removed by passage through a 250 microm rotary screen.     

Effects of sodium, potassium and calcium on salt-stressed barley

We grew barley ( Hordeum vulgare L. CM 72) for a 28-day period and sequentially harvested plants every 3 or 4 days. Plants were salt-stressed with either NaCl or KCl (125 m M ) with or without supplemental Ca (10 or 0.4 m M final concentration, respectively). We determined tissue concentrations of Na, Ca, Mg, K. S, P, Fe, Mn, Cu and Zn for each harvest date by inductively coupled plasma spectrometry. Uptake (specific absorption rate) was calculated from the element content and growth rates. Salinity had significant effects on the uptake and concentrations of most elements. Mg and Mn concentrations declined with time. The concentrations of all other elements determined increased over time. Element uptake on a root dry weight basis declined with time. Three variables were significantly affected by salinity and correlated with growth; 1) the Ca concentration, 2) the total sum of the cation concentration (TC), and 3) the Mn concentration of the shoot. Salinity reduced Ca uptake and concentrations. Supplemental Ca increased Ca concentrations and was positively correlated with growth during salt stress. Salinity doubled TC, which was negatively correlated with relative growth rate (RGR). Relative growth rate declined at TC values above 150 m M . Salinity reduced the uptake and concentration of Mn. Manganese concentrations in the shoot were highly correlated with RGR. Relative growth rate declined at Mn concentrations below 50 nmol (g fresh weight)⁻¹.