NaCl和Na2CO3胁迫对桑树幼苗生长和光合特性的影响

以1年生“青龙桑”幼苗为试验材料,研究了中性盐(NaCl)和碱性盐(Na2CO3)胁迫下桑树幼苗的生长和叶片光合特性.结果表明： 盐胁迫明显降低了桑树幼苗的株高、叶片数、生物量和叶片的光合能力.随着Na+浓度的增加,桑树叶片的气孔导度、蒸腾速率、净光合速率、实际光化学效率、电子传递速率和光化学猝灭系数明显降低,过剩光能以非光化学猝灭形式耗散的比例增加,桑树叶片的光能转化效率和光合能力下降.在Na+浓度＜150 mmol·L-1时,桑树幼苗的光合能力和生长受到的抑制较小,通过增加根冠比进一步适应盐胁迫,但这种保护机制随着盐浓度的增加逐渐降低.在Na2CO3胁迫下,＞50 mmol·L-1Na+浓度对桑树的生长和光合能力表现出较强的抑制作用,并随Na+浓度的增加,抑制程度加大.在NaCl＜150 mmol·L-1时,桑树的光合能力主要依赖植株形态和光合代谢双重途径适应中性盐逆境,而在NaCl浓度＞150 mmol·L-1和碱性盐胁迫下,其主要依赖光合代谢来适应逆境.     

细虫草胞外多糖对小鼠腹腔巨噬细胞免疫功能研究

本实验在体外条件下,以人工发酵培养的细虫草胞外多糖OgE、OgE-F1和OgE-F2作用于小鼠腹腔巨噬细胞RAW264.7,通过测定其对巨噬细胞的增殖率、代谢MTT活力、NO分泌和吞噬能力的影响,评价细虫草胞外多糖的免疫调节活性。结果表明,细虫草多糖对巨噬细胞无细胞毒性,且能促进巨噬细胞代谢MTT活力;在0.2mg/mL^1.0mg/mL浓度范围内,多糖呈剂量依赖性的促进巨噬细胞分泌NO水平和吞噬能力。本研究表明,细虫草多糖能有效地增强小鼠巨噬细胞的活性,潜在地可改善小鼠的先天性免疫调节。     

海草形态、生长的种间差异及其相关生长关系

海草是海洋沉水高等植物,属典型的根茎克隆植物.根状茎直径和分株重分别是其个体大小的第一、二表征指标,个体大小是海草重要的种间识别特征.对海草6个形态构件指标和18个生长指标的综合分析表明:果实大小、单株叶面积、分株重具有显著的种特异性;分株发出的时间差、水平根状茎分枝率、叶年产量、分株寿命和垂直茎分枝率是海草种特异性最强的5个生长动态指标,海草生长动态的差异主要体现在克隆生长能力强弱和分株生活史长短上;大海草趋于游击型克隆构型,而小海草则趋于密集型,但小海草Cymodocea nodosa例外;大海草基株水平扩展能力较小海草差.海草个体大小与生长特征的相关生长关系表明:随个体的增大,海草在有机构件生长上表现出两相邻叶、相邻分株、相邻节发出的时间差延长,分株、叶、茎寿命延长的特点;在克隆生长水平上表现出根状茎节间长变短、延伸速率降低,分枝率和根状茎上年产分株数降低,分枝角度变小和间隔子增大的趋势;在克隆片段水平上表现为生理整合性增强;在种群层面则表现出生物量增大和种群密度降低的特点.因此,海草个体大小对其形态、生长特征、克隆构型、种群密度和生产力起到了决定作用.大小海草不同的形态、生长动态和克隆构型特征导致它们的生存策略及生态功能也不同,这一点可能对海草场修复基础理论研究具有一定的指示作用.     

裸子植物雄球花——纤细堆囊穗的修订

研究了采自中国东北晚三叠世羊草沟组的一种裸子植物雄球花——纤细堆囊穗。通过对新材料的研究,发现这种雄球花小孢子叶末端的裂片在形态上差异很大,这是原来没有发现的十分重要的特征。这些保存精美的化石对于纤细堆囊穗特征的阐明和修订以及物种复原很有帮助。将中国的标本与西伯利亚堆囊穗、小堆囊穗、乌尔马堆囊穗和被定为长叶拜拉的雄球花进行了比较,发现它们与纤细堆囊穗在特征上一致,故将它们处理为纤细堆囊穗的异名。修订后的纤细堆囊穗包括上面所提到的所有种。同时,也讨论了堆囊穗属可能的演化意义。它可能是银杏属的远祖,经过小孢子囊数目的减少和小孢子叶长度的缩短而演化到现在的银杏,而产自辽西早白垩世的辽宁银杏可能代表了堆囊穗和现代银杏在形态演化上的一个中间步骤。     

长江口棘头梅童鱼食物组成和摄食习性的季节变

棘头梅童鱼是长江口水域的常见小型经济鱼类,具有一定的捕捞价值.为了解长江口棘头梅童鱼食物组成和摄食习性的季节变化,本研究利用胃含物分析法对2013年11月—2014年8月在长江口水域捕获的棘头梅童鱼样本进行了分析.结果表明：长江口棘头梅童鱼全年摄食的饵料生物有8目30种,其中虾类(游泳亚目)是主要饵料生物,相对重要性指数百分比(IRI%)为38.5,优势指数(Ip)为79.1;其次为糠虾目和磷虾目.全年饵料生物中的主要优势种类为葛氏长臂虾、安氏白虾、脊尾白虾、长额刺糠虾、短额刺糠虾、光背节鞭水虱和中华哲水蚤等.饵料生物优势种存在季节差异,春季和夏季的主要优势种均为葛氏长臂虾、安氏白虾和短额刺糠虾,秋季主要优势种为长额刺糠虾、短额刺糠虾和脊尾白虾,冬季主要优势种为葛氏长臂虾、中华哲水蚤和中华假磷虾.长江口棘头梅童鱼全年空胃率为10.4%,冬季最高,秋季最低;全年平均胃饱满系数为0.6%,冬季最低,春季最高,摄食习性存在季节变化.     

Comparative assessment of the Euglena gracilis var. saccharophila variant strain as a producer of the β‐1,3‐glucan paramylon under varying light conditions

Euglena gracilis Z and a “sugar loving” variant strain E. gracilis var. saccharophila were investigated as producers of paramylon, a β‐1,3‐glucan polysaccharide with potential medicinal and industrial applications. The strains were grown under diurnal or dark growth conditions on a glucose–yeast extract medium supporting high‐level paramylon production. Both strains produced the highest paramylon yields (7.4–8 g · L^?1, respectively) while grown in the dark, but the maximum yield was achieved faster by E. gracilis var. saccharophila (48 h vs. 72 h). The glucose‐to‐paramylon yield coefficient Y_par/glu = 0.46 ± 0.03 in the E. gracilis var. saccharophila cultivation, obtained in this study, is the highest reported to date. Proteomic analysis of the metabolic pathways provided molecular clues for the strain behavior observed during cultivation. For example, overexpression of enzymes in the gluconeogenesis/glycolysis pathways including fructokinase‐1 and chloroplastic fructose‐1,6‐bisphosphatase (FBP ) may have contributed to the faster rate of paramylon accumulation in E. gracilis var. saccharophila . Differentially expressed proteins in the early steps of chloroplastogenesis pathway including plastid uroporphyrinogen decarboxylases, photoreceptors, and a highly abundant (68‐fold increase) plastid transketolase may have provided the E. gracilis var. saccharophila strain an advantage in paramylon production during diurnal cultivations. In conclusion, the variant strain E. gracilis var. saccharophila seems to be well suited for producing large amounts of paramylon. This work has also resulted in the identification of molecular targets for future improvement of paramylon production in E. gracilis , including the FBP and phosophofructokinase 1, the latter being a key regulator of glycolysis.     

Development of microtopography in a semi-arid grassland: Effects of disturbance size and soil texture

Our objective was to evaluate effects of disturbance size and soil texture on the development of microtopography for a shortgrass plant community in north central Colorado USA. Disturbances, defined as the death of individual plants, were created in 1984 and 1985 to evaluate development through time of the small-scale pattern of perennial bunchgrasses and bare soil openings that characterize this semiarid grassland. Disturbed plots of three sizes (50, 100, 150 cm-diameter) comparable in size to naturally-occurring disturbances were produced by killing plants at two sites differing in soil texture (sandy loam, clay loam). Disturbed plots were not manipulated after being created. In 1993, a laser surveying instrument was used to measure heights of crowns of individual plants of the dominant species, the perennial bunchgrass Bouteloua gracilis ([H.B.K.] Lag. ex Griffiths), and bare soil openings between plants for two locations: within each disturbance and in the surrounding undisturbed landscape.Differences between crown heights of plants and bare soil openings were comparable for both the undisturbed landscape and inside disturbances indicating that small-scale microtopography had recovered within nine years after disturbance occurred. However, complete recovery to the undisturbed state had not occurred since crown heights of plants relative to bare soil openings were significantly less on disturbed than undisturbed locations. Differences in height between plant crowns and bare soil openings on disturbed plots increased as disturbance size increased, indicating greater soil redistribution with increasing plot size. Larger differences in height were also found on plots on the fine- than the coarse-textured soil, indicating the importance of soil particle size and plant cover type to the development of microtopography. Differences in height between microsites on disturbed plots were positively related to total plant cover and negatively related to cover of B. gracilis indicating the importance of this species to reducing erosion on disturbed areas.In this semiarid grassland, patterns in microtopography were heterogeneous, likely as a result of the small-scale redistribution of soil between bare soil openings and B. gracilis plants through time. Our results indicate that this redistribution of soil is affected by disturbance size, soil texture, and patchy plant cover. The major effect of small-scale disturbances on patterns in microtopography of the shortgrass steppe are causing plant death and exposing soil to erosional and depositional processes.     

Responses of a C3 and a C4 perennial grass to elevated CO2 and temperature under different water regimes

An experiment was carried out to determine the effects of elevated CO₂, elevated temperatures, and altered water regimes in native shortgrass steppe. Intact soil cores dominated by Bouteloua gracilis, a C₄ perennial grass, or Pascopyrum smithii, a C₃ perennial grass, were placed in growth chambers with 350 or 700 μL L^?1 atmospheric CO₂, and under either normal or elevated temperatures. The normal regime mimicked field patterns of diurnal and seasonal temperatures, and the high-temperature regime was 4 °C warmer. Water was supplied at three different levels in a seasonal pattern similar to that observed in the field. Total biomass after two growing seasons was 19% greater under elevated CO₂, with no significant difference between the C₃ and C₄ grass. The effect of elevated CO₂ on biomass was greatest at the intermediate water level. The positive effect of elevated CO₂ on shoot biomass was greater at normal temperatures in B. gracilis, and greater at elevated temperatures in P. smithii. Neither root-to-shoot ratio nor production of seed heads was affected by elevated CO₂. Plant tissue N and soil inorganic N concentrations were lower under elevated Co₂, but no more so in the C₃ than the C₄ plant. Elevated CO₂ appeared to increase plant N limitation, but there was no strong evidence for an increase in N limitation or a decrease in the size of the CO₂ effect from the first to the second growing season. Autumn samples of large roots plus crowns, the perennial organs, had 11% greater total N under elevated CO₂, in spite of greater N limitation.