Phenylpropanoid amides of serotonin accumulate in witches' broom diseased bamboo

Aciculosporium take (Ascomycota; Clavicipitaceae), causes the witches' broom disease in bamboo, particularly Phyllostachys bambusoides. Since it was observed that endogenous indole-3-acetic acid is reduced in the twigs of the diseased bamboo, the symptoms (bushy appearance) may be induced by reduction in auxin levels. Furthermore, two indolic compounds accumulated in diseased twigs, these being identified as N-p-coumaroylserotonin and N-feruloylserotonin by LC-MS, 1H NMR and 13C NMR spectroscopic analyses. N-p-Coumaroylserotonin possesses antifungal activity against A. take.     

Carbon and nutrient dynamics in relation to growth rhythm in the giant bamboo Phyllostachys pubescens

The carbon and nutrient dynamics in relation to growth rhythm in the giant bamboo Phyllostachys pubescens on Mount Jinyun, Chongqing, China, was studied during 1993–1996. Concentrations of TNC (total non-structural carbohydrates), N, P, and K all showed the same distribution pattern among organs: leaves > branches rhizomes stems roots. The rapid spring growth of new shoots noticeably reduced the concentration of TNC in the rhizomes, in which a large amount of carbohydrates was stored. The N concentration of the rhizomes did not decrease, however. Nutrient concentration of new (1st-year) leaves was significantly higher than that of old (2nd-year) leaves. Although the density of adult shoots was almost the same during 1994–1996, the low ratio of the number of adult shoots with new to that with old leaves from June 1994 to April 1995 resulted in a low TNC concentration in the rhizomes in early spring (April) 1995. This led to a low production of new shoots in the spring of 1995, their number being only ca. 10% of that in 1994 and 1996. Before old leaves were shed, a large amount of nutrients was remobilized and translocated to other plant parts to support further growth. Fertilization with NPK significantly increased the concentrations of N and P in leaves and subsequently increased the number of emerging new shoots.     

Growth and nitrogen utilization in seedlings of mountain birch (Betula pubescens ssp. tortuosa ) as affected by ultraviolet radiation (UV-A and UV-B) under laboratory and outdoor conditions

 Growth patterns and nitrogen economy were studied in pot-grown seedlings of mountain birch subjected to different ultraviolet radiation under both laboratory and outdoor conditions at Abisko in northern Sweden. In the laboratory, nutrient supply, temperature, humidity, ultraviolet radiation-A (UV-A, 320–400 nm) and B (UV-B, 280–320 nm) were controlled, while photosynthetically active radiation (PAR, 400–700 nm) and photoperiod varied naturally. Under outdoor conditions nutrient supply was controlled, and the irradiation treatments were ambient and above-ambient UV-B using additional fluorescent lamps. Mountain birch nitrogen economy was affected by increased ultraviolet radiation, as reflected by a changed relationship between plant growth and plant nitrogen both in the laboratory and outdoors. In the laboratory enhanced UV-A decreased leaf area per unit plant biomass (leaf area ratio) but increased biomass productivity, both per unit leaf area (leaf area productivity) and per unit leaf nitrogen (leaf nitrogen productivity). Low levels of UV-B affected growth patterns and nitrogen economy in a similar way to enhanced UV-A. High levels of UV-B clearly decreased relative growth rate and nitrogen productivity, as leaf area ratio, leaf area productivity and leaf nitrogen productivity were all decreased. Under outdoor conditions above-ambient levels of UV-B did not alter growth or biomass allocation traits of the seedlings, whilst nitrogen productivity was increased. Mountain birch seedlings originating from different mother trees varied significantly in their responses to different ultraviolet radiation. Received: 10 April 1997 / Accepted: 19 September 1997     

Impact of Phyllostachys heterocycla ‘Pubescens’ expansion on mycorrhizal associations of the adjacent forests

 毛竹(Phyllostachys heterocycla ‘Pubescens’)凭借其独特的生长特性极易扩张进入周边的常绿或针阔混交森林群落并取而代之。菌根减弱假说对毛竹林扩张导致周边林分枯亡并抑制林下幼苗更新的机制进行了解释, 即毛竹林的成功扩张是由于毛竹蔓延引起森林群落的菌根系统紊乱, 使宿主植物与菌根真菌的共生关系受到干扰, 进而影响了宿主植物的分布与更新。该研究以浙江省西天目山国家自然保护区为研究区域, 对菌根减弱假说进行了检验。通过在毛竹-针阔混交林交接区沿毛竹扩张方向设置毛竹纯林、竹-林过渡带、针阔混交林3种类型的样带, 选取在针阔混交林、竹-林过渡带同时存在的6种优势乔灌树种——杉木(Cunninghamia lanceolata)、枫香树(Liquidambar formosana)、青冈(Cyclobalanopsis glauca)、柳杉(Cryptomeria fortunei)、江浙山胡椒(Lindera chienii)、毛柄连蕊茶(Camellia fraterna), 测定这6个树种在两样带中的菌根侵染频率和强度, 检测在毛竹林扩张中周边森林群落菌根的响应, 同时对比了毛竹在毛竹纯林和竹-林过渡带菌根感染率和强度的变化, 检验该假设。实验结果表明: 1)针阔混交林和竹-林过渡带的主要树种菌根都具有较高的菌根侵染频率(> 95%), 且不同林分间林木的侵染频率无显著差异(p > 0.1); 2)在竹-林过渡带杉木和江浙山胡椒的丛枝菌根侵染强度较针阔混交林明显增加(p < 0.1); 3)毛竹的丛枝菌根侵染频率和强度远低于其他针阔树种, 且在扩张前后没有显著变化(p > 0.1)。实验结果否定菌根减弱假说。     

盐胁迫对2种珍贵速生树种种子萌发及幼苗生长的影响

以1/2Hoagland营养液为基础培养液,研究了在0.1%、0.2%、0.4%和0.6%NaCl胁迫条件下,毛红椿〔Toona ciliata Roem. var. pubescens(Franch.)Hand.-Mazz.〕和水松〔Glyptostrobus pensilis(Staunt.ex D.Don)K.Koch〕的种子萌发和幼苗生长情况。结果表明,随着NaCl浓度的增加,2个树种的种子萌发率和简化苗木活力指数均明显下降,在0.1%、0.2%、0.4%和0.6%NaCl胁迫条件下,毛红椿和水松种子的最终萌发率分别为89.3%、87.3%、62.7%、32.0%和26.0%、16.7%、6.0%、3.3%,简化苗木活力指数分别为1.39~0.08和1.52~0.07,且毛红椿的种子萌发率和简化苗木活力指数均明显高于水松。萌发恢复实验结果表明,高浓度NaCl处理后的种子具有较高的萌发恢复率。根据实验结果初步判定毛红椿种子具有较强的耐盐性。     

长期淹水环境下河竹鞭根系统形态、生物量和养分的适应性调节

为揭示长期淹水环境下基于形态、生物量和养分的河竹鞭根系统的生长策略,为河竹在水湿地和江河湖库消落带植被恢复中的应用提供参考,调查测定了人工喷灌供水和淹水处理3、6、12个月的河竹一年生竹鞭及其根系的形态和生理生化指标,分析了河竹鞭和鞭根形态特征和生物量分配及鞭根系统的养分吸收与平衡.结果表明: 长期淹水对河竹鞭节长、鞭径和土中根根径并无明显影响.淹水3个月整体上对鞭的形态特征影响小,水中翘鞭较少,但一定程度上抑制了根的生长.随着淹水时间的延长,水中鞭、根大量生长,同时促进了土中鞭、根的生长,但土中、水中鞭生物量和土中根生物量占总生物量的比例变化并不明显,而水中根生物量/总生物量和水中根生物量/土中根生物量显著升高,体现出河竹可以通过鞭根系统的生长调节和生物量合理分配来逐步适应淹水环境.长期淹水整体上降低了河竹土中根的根系活力,抑制了土中根对养分的吸收,但对土中根养分化学计量比的影响较小,而使水中根的根系活力显著增强,养分化学计量比产生明显的适应性调节,N/P升高,N/K和P/K降低.水中根不仅起到氧气吸收功能,还具有较强的养分吸收功能.这是河竹有效适应淹水环境的生长策略之一.     

长期淹水对河竹鞭根养分化学计量特征的影响

以长期淹水环境下能生长更新的河竹为材料,调查测定了人工喷灌供水(CK)、淹水6个月(TR)的河竹一年生竹鞭的根生物量和主要养分元素含量,分析长期淹水对河竹鞭根养分化学计量特征的影响,为河竹在水湿地和消落带植被恢复中的应用提供理论依据。结果显示:(1)与CK相比,TR处理下的河竹土中根的N、P、Mg和Ca含量显著降低,Fe含量显著升高,且N、K和Ca含量显著低于TR处理下水中根的含量,而Fe含量显著高于水中根。(2)TR处理的河竹土中根的C/N、C/P、C/K和P/K较CK显著升高,且C/K、N/K和P/K显著高于TR处理的水中根。(3)TR处理的河竹水中根的C-N、C-P、N-P均呈极显著正相关关系,土中根的C-P、C-K、P-K均呈极显著正相关关系;CK河竹土中根的C-P、C-K呈极显著正相关关系,且N-P显著相关;从相关系数看,TR处理下土中根的C-N、N-P和N-K相关性减弱,C-P、C-K和P-K相关性增强,而C-N、C-P、N-P和N-K相关性较水中根减弱,C-K和P-K相关性较水中根增强。(4)TR处理下鞭根生物量和C、N、P、K、Mg、Ca积累量较CK分别显著降低19.46%、42.04%、36.55%、41.39%、60.06%和38.46%,而Fe积累量显著升高,为CK的5.5倍;TR处理下土中根养分积累量显著高于水中根。研究表明,长期淹水虽阻碍了河竹鞭根的养分平衡吸收,但能够提高养分利用效率,并且土中根和水中根具有克隆分工特征,水中根主要起到氧气吸收应对缺氧环境胁迫的功能,是河竹适应长期淹水环境的重要生态对策。     

长期施用不同肥料对红哺鸡竹林叶片碳、氮、磷化学计量特征的影响

为了给笋用竹林土壤合理补充养分提供科学依据,以红哺鸡竹(Phyllostachys iridescens)为对象,开展了长期施用不同肥料(生物有机肥、复合肥、菜籽饼肥和不施肥(对照))竹林2年生立竹叶片C、N、P化学计量学特征的研究。结果表明:叶片C、N、P含量分别为514.26～582.77、18.25～30.20、1.20～1.75mg·g-1,施肥竹林均极显著或显著高于对照竹林,以施菜籽饼肥竹林叶片C含量最高,施生物有机肥竹林叶片N、P含量最高;叶片C:N、C:P分别为18.71～35.02、304.41～458.52,总体上施肥竹林较对照竹林极显著降低,施肥竹林N、P养分利用效率显著降低;叶片N:P为15.28～17.12,相对稳定,施肥竹林与对照竹林无显著差异;叶片N、P含量呈极显著正相关,N含量与N:P相关性不显著,而P含量与N:P呈极显著负相关。     

珍稀濒危树种毛红椿微卫星DNA分离及SSR反应体系优化

本研究以江西宜丰种源毛红椿为材料,成功提取其基因组DNA。利用改良的链亲和素磁珠法亲和捕捉出毛红椿基因组微卫星DNA片断,并构建了富含微卫星的基因组文库。从构建的基因组文库中随机挑选了63个单克隆进行测序,其中50个单克隆成功测序,含有微卫星的单克隆有18个,并根据测序结果设计并合成SSR引物18对。利用所合成的引物优化SSR反应体系,对影响SSR反应的各个因子进行了探讨。确定了模板DNA浓度最适浓度为30ng;dNTP的最适浓度为0.3mmol·L-1;0.3μmol·L-1是引物在反应体系中的最合适浓度。建立了重复性好、稳定性好的SSR反应体系,为下一步进行毛红椿群体遗传结构和遗传变异研究提供了技术支持。     

The responses of Moso bamboo (Phyllostachys heterocycla var. pubescens) forest aboveground biomass to Landsat TM spectral reflectance and NDVI

Bamboo is a special forest type in subtropical regions of china. Its huge biomass and carbon storage and its ecological function play an important role in global carbon sink. In this paper, Moso bamboo (Phyllostachys heterocycla var. pubescens) forest in Anji county, Zhejiang province, China was selected to examine the relationships between Landsat Thematic Mapper (TM) data, and aboveground biomass (AGB, Kg), This research indicates that (1) near infrared (TM4) and mid-infrared bands (TM5,TM7) are more important in explaining Moso bamboo AGB than the visible bands. In particular, TM band5 has higher path coefficient with AGB than any other TM bands, implying its important role in explaining Moso bamboo AGB; (2) the Normalized Difference Vegetation Index (NDVI) has weak correlation with Moso bamboo AGB, however, other vegetable indices such as Perpendicular Vegetation Index (PVI), Enhanced Vegetation Index(EVI), and Soil Adjust Vegetation Index (SAVI) which are related to soil adjustment parameters are significantly correlated with Moso bamboo AGB; (3) the new vegetation index developed in this paper is significantly correlated with Moso bamboo AGB (correlation coefficient is 0.48), and has higher correlation coefficient (R) than any other selected vegetation indices, implying that this new vegetation index can better explain Moso bamboo AGB than any other vegetation indices.