慈竹构件和分株水平总黄酮含量的变化

黄酮类化合物是植物体内重要的次生代谢物质之一。本文采用AlCl3 比色法测定了慈竹构件和分株水平总黄酮含量的变化 ,以探讨其生理生态适应性。结果表明 ,在地上 3个构件中 ,叶的总黄酮含量显著大于枝和秆 ;1龄分株叶的总黄酮含量显著大于其它 4个龄级 ,而枝和秆的含量在 5个年龄间无显著差异 ;分株上层叶和枝条的总黄酮含量显著多于中下两层的相应构件。叶龄对慈竹叶总黄酮含量有显著的影响 ,1龄、 7龄和 9龄叶片的总黄酮含量明显高于其它 6个龄级 ,但是叶龄和总黄酮含量之间无显著线性相关。同时 ,叶总黄酮含量对季节的变化敏感 ,2、 4和 12月含量最高 ,5月和 8月含量最低。在分株水平 ,1龄分株的总黄酮含量显著大于其它 4个龄级。这些结果说明慈竹的总黄酮含量对环境变化具有可塑性 ,分株水平与叶构件水平总黄酮含量对分株年龄的反应格恐相同。     

不同支持物对攀援植物--葎草雌雄株光合特性及生物量结构的影响

葎草[Humulus scandens(Lour.)Merr.]为草本雌雄异株攀援植物,采用野生种群人为控制的方法,设置分枝找到乔木支持物(高度(3±0.5)m)、灌木支持物(高度(1±0.5)m)和无支持物3种生长方式,测定雌(♀)、雄(♂)株分枝的叶面积参数、光合参数、叶绿素含量、可溶性糖含量及茎、叶、花在分枝、构件、单株水平下生物量分配比等指标,分析支持物对分枝光合特性和生物量结构的影响,探讨雌、雄分枝利用支持物的性别差异及响应支持物的生态适应差异。结果表明:(1)分枝的单叶面积、总叶面积、叶面积比率、比叶面积对支持物响应存在性别差异,♀株叶面积参数均大于♂株;支持物差异主要影响叶绿素a含量,对叶绿素b、叶绿素a/b影响不显著。(2)支持物差异对分枝叶片的光合参数均有显著的影响(P0.05),支持物对光合参数影响顺序为GsPnTrCi,性别差异影响顺序为GsTrPnCi;可溶性糖含量在性别间、支持物间均表现出极显著的差异(P0.01),♂株糖含量显著高于♀株。(3)在分枝水平下,♀株叶、茎及花生物量分配比都未受到支持物不同的影响(P≥0.05),而♂株在叶、茎的生物量分配比方面受影响显著(P0.05);在构件水平下,支持物差异显著影响了♂株分枝间的营养生长构件分配比,显著影响了♀株分枝间的生殖生长构件分配比;在单株水平下,叶分配比仅在支持物间差异显著(P0.05),而茎、花分配比在性别间、支持物间均有显著差异。(4)雌雄分枝的光合特性和生物量结构对不同支持物的响应差异明显,使葎草单株的生理整合性和适应性大幅度提高。研究以雌雄异株攀援植物为材料,从分枝水平分析支持物对雌雄株光合特性及生物量结构的影响,研究结果对探讨雌雄异株攀援植物的生态适应性具一定的价值。     

慈竹无性系种群能值特点及其影响能值计测因素的研究

 本文引用Harper(1977)的构件结构理论,从构件结构单位、无性系分株和无性系三个层次,对四川南充市郊慈竹无性系种群的能值特点及其影响能值的计测因素进行了定量研究。研究结果表明：慈竹无性系种群中,各构件单位的去灰分热值(AFCV)分别为：根15349.42J／g、根茎16372.92J／g、秆17106.06J／g、枝18111.99J／g和叶19451.90J／g;慈竹无性系分株的AFCV(J／g)随龄级增大而递增;慈竹无性系水平上的AFCV为：Ⅰ龄占16.47%、Ⅱ龄占25.76%、Ⅲ龄占36.32%、Ⅳ龄为13.08%及Ⅴ龄为8.37%。用恒容燃烧法测定热值时,其能值变化与氧分压密切相关。用经验公式计算的能值较作图法高;用AFCV表示能值较总干重热值(GCV)准确。     

慈竹克隆种群能量动态研究

本文引用Ｈａｒｐｅｒ的构件结构理论,从克隆构件,克隆分株和克隆种群３个层次,系统探索我国特有种慈竹克隆种群能量动态,研究结果表明：慈竹克隆种群单位量能值变化随其生长季节,生长发育阶段和年龄不同而异,冬季单位能值升高,换叶期单位能值聚然下降;生殖阶段单位能值降低,但龄级间差异较大,慈竹克隆种群具整合作用。影响慈竹克隆种群能量变动的因素主要是大气温度,湿度和种群生殖与换叶等。     

LED短期连续光照与氮营养对水培生菜品质的影响

设置10和15 mmol·L^-12个氮水平处理,NO₃^- -N∶NH₄⁺-N比例分别为1∶0、4∶1和1∶1的3个氮形态处理,水培紫叶生菜,研究其在LED红蓝组合光短期连续光照(SCL)后的品质提升效果.结果表明： 各处理生菜地上部干质量在LED光源SCL处理后均显著提高,最小增幅为35.1%,根系干质量除NO₃^- -N∶NH₄⁺-N为1∶1且氮水平为15 mmol·L^-1的处理和NO₃^- -N∶NH₄⁺-N为1∶0且氮水平为10 mmol·L^-1的处理外,差异都达到显著水平.SCL处理前,不同氮营养处理生菜总酚、类黄酮相对含量差异不显著.SCL处理后,不同氮营养条件下生菜总酚、类黄酮和花青素相对含量差异显著.2种氮水平下,总酚和类黄酮相对含量随铵氮比例的提高而增加,花青素相对含量随铵氮比例增加而先降低后升高.SCL处理使生菜叶片、叶柄硝酸盐含量显著降低,其中叶片硝酸盐含量降低23.2%,生菜叶片抗坏血酸、可溶性糖和可溶性蛋白含量均显著提高.叶片硝酸盐含量降低速率随氮水平和铵氮比例的增加而提高.抗坏血酸含量增加速率主要受氮水平影响,氮水平较低时抗坏血酸含量增加速率较高.可溶性糖含量增加速率随着铵氮比例的增加而增加.SCL处理显著提高了不同氮营养水培生菜干物质的积累,同时显著降低了硝酸盐的积累,显著提高了抗坏血酸、可溶性糖和可溶性蛋白含量,氮营养条件对SCL改善生菜品质的速率有显著影响.     

养分异质条件下结缕草克隆分株生长、碳水化合物及可溶性蛋白的生理整合

通过对连接和断开的结缕草分株进行不同的养分处理,研究了养分异质条件下结缕草克隆分株生长、碳水化合物及可溶性蛋白含量的变化.结果表明: 在养分异质条件下,处于中、高养分水平的母株可以显著提高与其相连子株的地上、地下及总生物量,高养分下分别提高32.5%、22.1%和24.8%,降低根冠比、可溶性糖及非结构性碳水化合物(NSC)含量,高养分下分别降低7.7%、15.2%和13.1%,但是对淀粉、纤维素、可溶性蛋白含量无显著影响.处于中、高养分水平的子株对与其相连的母株生长、碳水化合物及可溶性蛋白含量没有显著影响.养分异质条件下结缕草母株对子株生物量、根冠比、可溶性糖及NSC含量有明显的生理整合,其整合强度与养分梯度呈正比,而对淀粉、纤维素及可溶性蛋白含量没有显现显著的生理整合效应.子株对母株各项指标都没有显著的生理整合,结缕草母株和子株间是一种单向的生理整合.     

不同季节干旱及复水对刺槐幼苗可溶性糖含量的影响

以刺槐(Robinia pseudoacacia)幼苗为材料,采用盆栽控水方法研究了春季、夏季和秋季干旱及旱后复水对刺槐幼苗可溶性糖含量的影响.结果表明:土壤水分胁迫程度对夏季刺槐幼苗可溶性糖含量影响显著,并且当土壤相对含水量低于52.16%并继续下降时可溶性糖含量迅速升高,而其对春季和秋季幼苗的可溶性糖含量影响不显著;春季和秋季不同胁迫历时处理间刺槐幼苗可溶性糖含量差异不显著,而夏季土壤相对含水量为52.16%和40%处理的可溶性糖含量显著高于对照;相同水分胁迫条件下不同季节刺槐幼苗可溶性糖含量总体表现为:秋季>春季>夏季.干旱复水后春季刺槐幼苗可溶性糖含量持续下降,而夏季呈现先升高后降低的趋势,秋季呈现一定波动性,变化幅度不明显.研究发现,刺槐幼苗可溶性糖含量在干旱及复水调节下的变化不仅受土壤水分胁迫强度和胁迫时间的影响,也与植物所处的生长季节有密切关系.     

保鲜液膜对板栗贮藏的效应（简报）

三种保鲜液膜处理的板栗,在常温下贮藏150d,好果率增大,失水率下降,呼吸显著受抑。总糖含量每隔30d以0．96％～1．19％速率递少;还原糖含量在0．9％～7.5％水平上呈动态平衡;可溶性蛋白在0.31％～0．59％间波动。各处理间的过氧化物酶活性差异较大,后期均低于对照。Vc含量变化不明显。     

雷竹克隆系统出笋期有机碳分布变化规律

植物光合碳同化物为植物的生长提供所需的物质和能量。目前,对植物有机碳分布虽已展开了大量研究,但对竹类植物出笋期有机碳转移机制的研究还比较缺乏。测定了分株数量为单株、双株和三株的雷竹克隆系统出笋期分株各器官的有机碳含量,以期进一步了解雷竹克隆系统出笋期有机碳转移变化规律。研究发现:雷竹分株不同器官有机碳含量差异显著,且在出笋期发生显著变化,出笋前:枝(52.64%)叶(47.18%)秆(40.98%)鞭(40.13%)根(35.14%),出笋完成后:枝(48.20%)秆(47.84%)叶(45.53%)鞭(45.52%)根(44.29%),枝、叶有机碳含量呈先下降后上升趋势,根、秆、鞭有机碳含量呈"N"型变化规律;单株、多株系统雷竹分株各器官有机碳含量降幅与出笋量成反比,随分株数量增加,出笋量增加,而各器官有机碳含量降幅减小;双株系统中1年生雷竹各器官有机碳含量降幅大于2年生竹,三株系统中3年生雷竹各器官有机碳含量降幅大于1年、2年生竹。这些结果表明:出笋影响雷竹各器官有机碳分配格局,出笋时各器官间有机碳资源发生转移,其中枝、叶有机碳含量降低而根、秆、鞭有机碳含量增加;各器官间源-汇关系发生变化,分株间有机碳资源存在共享,分株数量增加出笋量增加且系统内分株的损耗减小;分株年龄是影响雷竹不同器官出笋期有机碳含量变化的影响因素之一。因此,调整雷竹林年龄结构对提高雷竹林出笋量及经济效益有十分重要的现实意义。     

遮荫条件下黄檗生长和生理响应的性别差异研究

分析遮荫条件下黄檗幼苗形态指标、生理指标和代谢物质性别间差异，探讨其对遮荫的响应策略，为黄檗野生资源保护及造林抚育提供理论依据。以2年生黄檗雌雄株幼苗为试验材料，采用控制实验，设置3个遮荫梯度，自然光为对照，对比研究遮荫条件下黄檗幼苗雌雄植株形态特征、生物量分配、抗氧化防御酶活性、代谢物质的差异，以揭示其遮荫条件下的生存策略。结果表明：遮荫处理更有利于黄檗的生长，轻度遮荫雌株生物量积累大于雄株，重度遮荫后雄株大于雌株；遮荫处理对叶绿素a、总叶绿素含量均有显著影响（P<0.01），性别间差异不显著，遮荫条件有利于促进黄檗幼苗叶绿素积累；遮荫处理对酶活性和MDA含量均有显著影响，性别间差异不显著，SOD酶活性均随遮荫强度的增强而增大，POD和CAT酶活性随遮荫强度的增强而减小，MDA含量在对照处理时最高；遮荫条件下可溶性糖和可溶性淀粉含量下降，性别间差异不显著。黄檗幼苗通过改变构件性状、生物量、抗氧化酶活性及代谢物质含量，适应遮荫环境。研究遮荫对黄檗生长和生理响应的性别差异，以期为遮荫环境下黄檗个体发育、种群形成、适应机制及种群繁衍等研究奠定基础，为雌雄异株植物资源的保护利用提供科学借鉴。     

慈竹母株大小对克隆生长的影响

 克隆生长在慈竹种群更新中占有重要地位。本文以基径和生物量两个指标同时衡量慈竹(Neosinocalamus affinis)的母株大小,并分析了母株大小对新竹笋产生、竹笋大小和根茎大小的影响。结果表明：1）慈竹的成竹基径与一级母株基径、二级母株基径以及与2龄和3龄母株平均单株生物量呈正相关,但是成竹基径随一级母株基径增加比随二级母株基径增加而增加的速率快得多;2）慈竹母株大小与各样方中出笋数、活笋数和死笋数无显著的正相关;3）发笋母株的基径显著大于未发笋母株,但发一个笋母株与发两个以上笋母株的基径无显著差异;4）母株基径、2龄和3龄母株平均单株生物量都与根茎的长度和粗度呈显著正相关,且竹笋基径与根茎粗度也呈显著的正相关。母株大小对慈竹竹笋的影响是通过影响根茎实现的。总之,慈竹的克隆生长在个体水平受母株大小制约。     

缙云山慈竹种群生物量结构研究

 本文引用Harper的构件结构理论,从两个水平(即群落水平上的种群和个体水平上的种群)上研究了缙云山慈竹种群的生物量结构及其影响因素。 研究结果表明：(1)慈竹无性系种群中各个体生物量在1—5龄级的分配为：14.18%,24.22%,41.91%、12.30%和7.38%,种群现存生物量为156.407t·ha-1;(2)慈竹种群中,生物量在各构件单位的配置为：秆49.46%,枝21.34%,叶8.73%,根茎14.00%,根6.47%;(3)慈竹(合子)种群在200ha中的生物量为31281t。地上地下部分生物量各占种群总量的79.53%和20.47%。     

Differences in the structure, growth and survival of Parasenecio yatabei ramets with contrasting water relations on the slope of a stream bank

Parasenecio yatabei (Asteraceae), a summer-green perennial herb, is widely distributed on sloping mountain stream banks in cool-temperate zone forests of Japan. We investigated the growth pattern, leaf longevity and leaf water relations of vegetatively independent plants (ramets) growing in two contrasting soil water conditions, that is, upper and lower stream banks (U ramets and L ramets, respectively). The objective of the present study was to clarify the physiological and morphological responses of the ramets to soil water conditions. Dry matter allocation to subterranean parts was higher in U ramets than in L ramets. The U ramet leaves survived for approximately 2 months longer than L ramet leaves. The ratio of subterranean part to aerial part dry matter was greater in U ramets than L ramets. Leaf mass per leaf area (LMA) tended to be greater in U ramets than L ramets throughout the growing season. The leaf bulk modulus of elasticity at full hydration was significantly higher in U ramets. Thus, ramet growth patterns and morphological traits varied with changing soil water conditions. The greater longevity of U ramet leaves may play a role in compensating for the reduced annual net carbon gain caused by lower photosynthetic activity. U ramets growing in environments with less water availability achieved high water-use efficiency by a high passive water absorption capacity via a progressed root system and high productivity via longer leaf longevity with higher LMA and elasticity. Therefore, P. yatabei growing along mountain streams could have the ability to colonize the upper bank through higher survivorship based on these traits.     

美丽箬竹水分生理整合的分株比例效应——基于叶片抗氧化系统与光合色素

生理整合是克隆植物实现资源共享, 增强对异质生境适应能力的重要手段。其中, 水分生理整合是克隆植物最为重要的生理整合, 解析竹子水分生理整合特征对于竹林水分科学管理具有重要意义。该研究以分株地下茎相连的美丽箬竹(Indocalamus decorus)盆栽苗为试验材料, 设置2个盆栽基质相对含水率(高水势(90% ± 5%)和低水势(30% ± 5%))和5个分株比例(1:3、1:2、1:1、2:1、3:1, 高水势分株与低水势分株数量比值, 地下茎相连的分株总数12株)处理。处理后15、30、45、60天分别取不同处理的克隆分株成熟叶测定抗氧化酶活性、相对电导率和丙二醛含量、可溶性蛋白质含量、光合色素含量, 分析基于分株比例的美丽箬竹水分生理整合方向、强度和效率的变化规律。结果表明: 在异质水分条件下, 美丽箬竹分株间存在着从高水势供体分株向低水势受体分株进行水分转移的生理整合作用, 并随着分株比例的增大, 整合强度增强, 受体分株获益提高, 供体分株耗损增大。随着处理时间的延长, 处理前期分株间水分生理整合强度增强, 处理后期整合强度减弱, 反映出供体分株与受体分株间耗-益在时间序列上是有变化的, 处理前期耗-益更为明显。研究表明克隆系统分株比例对竹子水分生理整合有重要影响, 分株间水分梯度差是水分传导的潜在驱动力, 决定水分生理整合方向、强度和效率的是分株间水分供需关系。     

Response of physiological integration in Trifolium repens to heterogeneity of UV-B radiation

Physiological integration has been documented in many clonal plants growing under resource heterogeneity. Little is still known about the response of physiological integration to heterogeneous ultraviolet-B radiation. In this paper, the changes in intensity of physiological integration and of physiological parameters under homogeneous and heterogeneous ultraviolet-B radiation (280-315 nm) were measured in order to test the hypothesis that in addition to resource integration a defensive integration in Trifolium repens might exist as well. For this purpose, homogeneous and heterogeneous ultraviolet-B radiation was applied to pairs of connected and severed ramets of the stoloniferous herb Trifolium repens. Changes in intensity of water and nutrient integration were followed with acid fuchsin dye and ¹⁵N-isotope labeling of the xylem water transport. In order to assess the patterns of physiological integration contents of chlorophyll, ultraviolet-B absorbing compounds, soluble sugar and protein were determined and activities of superoxide dismutase (SOD) and peroxidase (POD) measured. When ramets were connected and exposed to heterogeneous UV-B radiation, the velocity of water transportation from the UV-B treated ramet to its connected sister ramet was markedly lower and the percentage of ¹⁵N left in labelled ramets that suffered from enhanced UV-B radiation was higher and their transfer to unlabelled ramets lower. In comparison with clones under homogeneous ultraviolet-B radiation, the content of chlorophyll, ultraviolet-B absorbing compounds, soluble sugar and activities of SOD and POD increased notably if ultraviolet-B stressed ramets were connected to untreated ramets. Chlorophyll and UV-B absorbing compounds were shared between connected ramets under heterogeneous UV-B radiation. This indicated that physiological connection improved the performance of whole clonal plants under heterogeneous ultraviolet-B radiation. The intensity of physiological integration of T. repens for resources decreased under heterogeneous ultraviolet-B radiation in favor of the stressed ramets. Ultraviolet-B stressed ramets benefited from unstressed ramets by physiological integration, supporting the hypothesis that clonal plants are able to optimize the efficiency of their resistance maintaining their presence also in less favorable sites. The results could be helpful for further understanding of the function of heterogeneous UV-B radiation on growth regulation and microevolution in clonal plants.     

Systemic induced resistance: a risk-spreading strategy in clonal plant networks?

Clonal plant networks consist of interconnected individuals (ramets) of different sizes and ages. They represent heterogeneous ramet assemblages with marked differences in quality and attractiveness for herbivores. Here, feeding preferences of a generalist herbivore (Spodoptera exigua) for differently-aged ramets of Trifolium repens were studied, and changes in herbivore preference in response to systemic defense induction were investigated. Dual-choice tests were used to assess the preference of herbivores for young versus mature ramets of induced and uninduced plants, respectively. Additionally, leaf traits related to nutrition, biomechanics and chemical defense were measured to explain variation in tissue quality and herbivore preference. Young ramets were heavily damaged in control plants. After systemic defense induction, damage on young ramets was greatly reduced, while damage on mature ramets increased slightly. Defense induction increased leaf strength and thickness, decreased leaf soluble carbohydrates and substantially changed phenolic composition of undamaged ramets connected to attacked individuals. Systemic induced resistance led to a more dispersed feeding pattern among ramets of different ages. It is proposed that inducible defense acts as a risk-spreading strategy in clonal plants by equalizing herbivore preference within the clone, thereby avoiding extended selective feeding on valuable plant tissues.     

Intraclonal variation in defence substances and palatability: a study on Carex and lemmings

Clonal sedges consist of integrated ramets at different development stages. Many of these sedges are important food for herbivores, yet differences in herbivore preferences and defence allocation between ramet development stages have not previously been evaluated. In this study we investigated intraclonal ramet variation in level of plant defence and nutrient compounds and intraclonal ramet preferences by lemmings ( Lemmus trimucronatus ) in field samples of a rhizomatous sedge ( Carex stans ). Plant defence was measured as the level of proteinase inhibitor activity (PIA) and the ratio of PIA to soluble plant proteins (SPP), whereas plant nutrients were measured as the level of soluble plant sugars (SPS) and SPP. Flowering ramets generally had a higher content of defence compared to vegetative ramets, which is consistent with the optimal defence theory predicting that defence compounds are allocated to the ramet stage of the highest fitness value. Compared to vegetative ramets, the flowering ramets had a lower content of SPP and a higher content of SPS. The lemmings showed preference differences between the ramet development stages, and to a large extent the ramet content of defence compounds and nutrient compounds covaried with these preferences in the predicted way. This study shows that defence allocation between ramet development stages of the clonal sedge Carex conforms to predictions of the optimal defence theory.