克隆水分整合有助胡杨无性系幼株在极端干旱生境下保持更高生存优势

以塔里木河下游的胡杨为对象,研究胡杨母株与其克隆幼株间的克隆水分整合特征及对克隆幼株生理机能的影响.结果表明: 胡杨母株与其克隆幼株间存在明显的以顶向传输为特征的水分整合,母株对克隆幼株的日平均水分整合流量为同区域长势相近的实生幼株通过自身根系日平均获取水量的3倍,克隆幼株因水分整合而能够获取与母株相似且较实生幼株水分来源相对较深层的土壤水,拥有更好的水分获取能力.这使胡杨克隆幼株较实生幼株保持显著更高的叶片水分含量,且黎明前和正午叶水势分别显著增加10.0%和29.7%.更好的水分生理状态使克隆幼株的光合电子传递速率与光适应下实际光化学效率显著高出实生幼株23.4%和11.5%,并能够保持显著更低的光系统Ⅱ过剩激能比例和光抑制风险.这可能让胡杨克隆幼株在极端干旱生境中较实生幼株保持更高的生存优势.     

克隆植物对异质生境的适应对策研究进展

生境异质性是自然生态系统的基本特征,植物生长的必需资源和环境胁迫因子均存在着复杂的时间和空间异质性。克隆植物是指在自然条件下具有克隆特性的植物,即可通过与母株相连的芽、根茎、分蘖或枝条等繁殖体产生无性繁殖的植物,这些繁殖体一旦定居便可成为潜在的独立个体。克隆植物具有独特的生境适应策略(如形态可塑性、克隆整合、克隆分工、觅食行为、风险分摊等),面对异质性的生境条件,它可以通过调整自身的生理和形态结构来适应异质生境。目前,对于克隆植物在异质生境适应行为的研究已有很多报道,然而系统性的归纳和总结尚有欠缺。综述了克隆植物在不同资源异质生境(光照、养分、水分)和不同胁迫生境(盐碱胁迫、风沙胁迫、重金属胁迫)下独特的适应对策。最后,针对克隆植物对异质生境的适应对策,进行了总结并对未来的重点研究方向提出建议：(1)时间异质性尺度上的考量;(2)异质性生境中生物因子的调控作用;(3)克隆植物入侵机制;(4)克隆植物在生态修复中的应用潜力。     

异质性水分环境中克隆整合对活血丹生物量分配及叶片结构特征的影响

喀斯特石漠化环境有着高度的生境异质性,异质性生境中土被不连续,土壤瘠薄,岩溶漏斗上的土壤保水性差,严重制约着喀斯特植被的生长及分布。为探究克隆植物在喀斯特地区的适应策略,本研究以喀斯特黄色石灰土为基质,选用克隆植物活血丹（Glechoma longituba）,以一个节间连接的两个分株为材料,保持节间连接或切断,种植于相邻花盆中,并施以不同浇水量,以明确不同水分可用性水平下克隆整合对活血丹生物量积累、生物量分配、叶片气孔及叶片组织特征的影响。结果显示,克隆整合显著促进活血丹生物量的积累及对根、叶的生物量分配;增加了活血丹叶气孔导度,降低了气孔指数;叶海绵组织受克隆整合影响较小,但栅栏组织及栅海比（栅栏组织/海绵组织）表现为非整合分株高于整合分株。本研究表明,克隆整合可增加活血丹胁迫分株对根、叶的投资,并以更佳的叶气孔、组织适应策略提高其在喀斯特生境中的生存与适应。     

克隆植物的水分生理整合及其生态效应

水分生理整合是克隆植物生理整合过程中非常重要的一部分,是克隆植物生长发育和生态适应过程中的重要机制之一。本文主要从理论上对克隆植物水分生理整合的存在性、方向性、整合的程度、范围及其与克隆植物的功能分工、表型可塑性和觅养行为、风险分摊等行为表现的关系进行了深入分析,并对迄今有关克隆植物水分整合的最新研究进展和研究方法进行了系统总结和评述。提出克隆植物的水分生理整合包括水平和垂直两个方向,而水力提降为垂直方向的水分生理整合提供了一个重要途径。认为在今后,应加强对克隆植物水分生理整合的精确定量化研究,同时,应运用生态学、生理学、生物化学及分子生物学等方法,综合深入地研究克隆植物水分整合的机理。     

水分胁迫条件下草莓克隆分株间水分调控及其对光合功能的影响

以盆栽草莓(Fragaria×ananassa)为材料研究了水分胁迫下克隆植物草莓母株和子株间的水分调控机制及其与碳同化、光系统Ⅱ激发能分配的关系.实验材料分为匍匐茎连接和剪断两个大组,进行两步实验.第1步实验,对连接组和剪断组的所有母株控水,子株充分供水;4d后进入第2步实验,把连接组分为两小组,对其中一组充分供水子株开始控水,另一组保持不变.结果表明,土壤干旱引起母株叶片失水,并使其净光合速率和气孔导度显著降低.但是连接组中供水良好的子株能有效缓解缺水母株的水分胁迫.当供水良好的子株也开始受到干旱处理的时候,则会加剧与之相连母株的水分胁迫.受胁迫母株可以通过加强渗透调节能力和降低水势从相连子株获取水分.虽然土壤干旱会造成受胁迫母株叶片脱落酸(abscisic acid, ABA)含量的大幅度增加,但是与之相连子株的叶片ABA含量并没有增加;并且气孔导度与ABA变化趋势一致.(1)草莓母株和子株间的水分运输是由二者的水势差驱动的;(2)ABA不会通过匍匐茎在母株和子株间传递并影响相邻子株气孔导度;(3)在水分异质性较大情况下,生理整合可明显提高克隆系统的碳同化能力和光系统Ⅱ激发能利用效率.     

Clonal integration affects growth and sediment properties of the first ramet generation,but not later ramet generations under severe light stress

克隆整合影响严重光胁迫下第一分株世代的生长和沉积物特征但不影响 后续分株世代的生长和沉积物特征 克隆整合通过缓冲环境压力和提高资源获取效率使克隆植物受益。然而,在一个克隆系统中,受益于克隆整合的连接分株世代的数量很少受到关注。我们进行了一个盆栽实验来评估沉水植物苦草 (Vallisneria natans)克隆系统内的生理整合程度,该克隆系统由一个母株和3个依次连接的后代分株组成。 母株生长在正常光照下,而后代分株被严重遮荫。母株与后代分株间的匍匐茎被切断或保持连接,但3个后代分株之间的连接仍然存在。与遮荫的后代分株连接时,苦草未遮荫的母株的光合能力显著增强,但其生物量积累大大减少。克隆整合显著增加了第一分株世代(相邻分株)的生物量积累和土壤的碳氮可用性、胞外酶活性和微生物生物量,但没有增加后续分株世代的这些特征。我们的结果表明,在严重光胁迫下,来自苦草母株的支持可能仅限于克隆系统中相邻的后代分株,这暗示着一个分株世代的效应。我们的结果有助于更好地理解克隆植物的层次结构和分段化。这些发现表明克隆整合程度在分株种群的生态相互作用中起着至关重要的作用。     

百山祖常绿阔叶林厚叶红淡比的萌蘖繁殖特性

克隆植物在群落更新和物种多样性的维持中起着重要的作用。目前克隆生态学很少涉及自然条件下乔木的研究。通过调查百山祖5 hm2的动态监测样地中随机选取的298株厚叶红淡比母株及其产生的萌蘖情况,分析它的克隆形态可塑性、径级结构及其影响因素,以及萌蘖对母株存活的影响。结果表明:母株间所带萌蘖数量差别较大,与母株的胸径正相关;82.79%的萌蘖在距母株30 cm以内;单棵母株所发萌蘖的数量和母株—萌蘖距离在四类生境间都无显著差异,但位于母株东侧的萌蘖显著多于母株西侧的;克隆群体与整个种群的径级结构存在差异,幼苗和幼树在克隆群体所占比例高于其在整个种群中所占的比例;而母株短期存活率与其所发萌蘖数量无关。厚叶红淡比在常绿阔叶林下的克隆繁殖显示出了独特的适应性,对维持群落的稳定具有重要意义。     

养分异质条件下结缕草克隆分株生长及光合作用的生理整合

通过对连接和断开的分株进行不同养分处理,研究养分异质条件下结缕草克隆分株生长及光合作用的变化.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提高与其相连子株的叶长、叶宽、根质量、叶质量、光合速率、气孔导度、蒸腾速率和水分利用效率,高养分条件下分别提高16.0%、8.3%、24.4%、58.1%、30.3%、54.0%、9.2%和21.9%,降低根冠比和胞间CO2浓度,在高养分下分别降低21.6%和31.5%;处于中、高养分水平的子株对与其相连母株的生长及光合特性没有显著影响.在养分异质条件下,结缕草母株对子株存在生理整合,养分梯度越大,整合强度越强.结缕草克隆子株可以从母株获益,但母株不能从子株获益,子株是生理整合单向获益者.     

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.     

胡杨幼苗根系生长与构型对土壤水分的响应

胡杨实生幼苗成活率低是制约其更新与人工育苗保存的关键问题,而幼苗根系生长与构型是影响其存活的重要因素。该试验以1年生胡杨幼苗为材料,通过2种给水方式(断续给水和连续给水)下各6个土壤水分梯度处理的控制试验,探究胡杨幼苗根系生长与构型对荒漠地区关键因子水分的响应特征。结果表明:(1)2种给水方式下干旱胁迫均使根冠比增加,且断续给水处理下幼苗根冠比显著大于连续给水。(2)一定程度的干旱处理还可以促进幼苗根系形态发育特征的发展和根系生物量的积累,但过度干旱胁迫或土壤水分含量过多都会抑制根系生长,并以连续给水、土壤含水量15%处理下幼苗根系最为发达。(3)幼苗深扎根能力强,其根宽深比在2种给水方式下均小于1,且断续给水处理显著小于连续给水处理;2种给水方式下根宽深比都与土壤水分含量呈显著正相关。(4)根系拓扑指数在2种给水方式下无显著差异且均接近1,但都与土壤水分含量呈显著负相关。即幼苗根系趋向鱼尾状分支结构,次级分支少,这种根系延伸策略有利于胡杨幼苗在干旱贫瘠的土壤环境中生存。(5)根系构型参数的主成分分析显示,总根长、总根表面积、根宽深比和拓扑指数在2种给水方式下都能很好地表示胡杨幼苗根系构型特征。可见,胡杨幼苗根系通过构筑鱼尾状分支结构、增加垂直根纵向延伸能力和增大根冠比适应干旱环境;水分对于胡杨幼苗根系生长与构型作用显著,根系对水分因子的响应对于胡杨幼苗适应水分异质性环境具有重要意义。     

Effects of nitrogen addition on clonal integration between mother and daughter ramets of Moso bamboo: a 13C-CO2 pulse labeling study

用¹³C-CO₂脉冲标记法研究氮添加对毛竹母子分株克隆整合的影响 相连分株间的资源共享(即克隆整合)是克隆植物的显著特征。克隆整合使毛竹(Phyllostachys pubescens)对多种环境条件具有较强的适应性。但毛竹通过克隆整合获得性能提升的机制尚不明确。本 研究区分并分析了毛竹光合碳的顶向整合和基向整合,以探究毛竹克隆片段如何在土壤氮异质性条件下 提高整体收益。本研究以由两株不同年龄毛竹分株组成 的克隆片段为研究对象,分株间通过根状茎连接。 每个分株设置氮添加或无氮添加两种处理,并通过单株母株或子株的¹³C-CO₂脉冲标记对光合碳的顶向整合和基向整合进行区分。研究结果表明,子株氮添加显著促进了光合碳由母株向子株的顶向整合,无论母株是否有氮添加,均向氮添加子株转运更多的光合碳。转运自无氮添加母株的光合碳主要分配至氮添加子株的 叶片,而转运自氮添加母株的光合碳则主要分配至根系。与无氮添加处理的子株相比,氮 添 加子株转运更多的光合碳至母株,且该过程不受母株氮添加的影响。转运自氮添加子株的光合碳主要 分配至无氮添加母株的根系和氮添加母株的叶片。这些结果说明,母株优先将更多的资源投入到具有高 养分可利用性的子株,随后子株作为更高效的资源采集点,根据母株的养分状况针对富集资源进行获取。通过这种方式,克隆植物可以降低资源获取成本并提高资源获取效率,最大限度地提升其整体表现。     

疏叶骆驼刺母株与子株间的水分整合

在未灌溉的土地上, 疏叶骆驼刺(Alhagi sparsifolia)通常不能进行有性繁殖, 克隆繁殖是其种群维持和延续的唯一方式。因此, 克隆性及其相关克隆性状(如水分整合)在疏叶骆驼刺自然种群的维持过程中可能扮演了极其重要的角色。该文通过疏叶骆驼刺母株和子株之间的间隔子切断和给母株补充水分的方法, 研究了母株和子株在各处理下的水势、叶形态和植株生长变化情况。结果表明: (1)间隔子切断后, 疏叶骆驼刺母株和子株正午水势均明显增大(p < 0.01), 说明间隔子切断使得母株和子株水分亏缺值都增大。(2)给母株补水后, 间隔子切断组和间隔子相连组中的母株水势均有明显增加, 同时间隔子相连组的子株水势明显增加(p < 0.01), 而间隔子切断组子株水势没有明显变化(p > 0.05)。(3)间隔子切断组的子株叶片含水率明显低于间隔子相连组子株, 而其株高、冠幅、分枝数和基径的增长量都明显小于间隔子相连组的子株(p < 0.01)。疏叶骆驼刺母株和子株间存在水分整合, 母株会通过根系向子株传输水分。研究成果对塔克拉玛干沙漠南缘的植被恢复以及水资源的合理利用有着重要的意义。     

Clonal integration enhances flood tolerance of Spartina alterniflora daughter ramets

Recently, considerable attention has been paid to the invasion of the clonal plant Spartina alterniflora into coastal wetlands at lower elevations. In this experiment, we tested whether clonal integration improved flood tolerance in S. alterniflora daughter ramets. Daughter ramets at two growth stages (young and old ramets) were flooded to water levels of 0, 9 and 18 cm above the soil surface, and the rhizomes between mother and daughter ramets were either severed or left intact. Biomasses of connected ramets grown in controls or in shallow and deep water treatments were 119%, 108% and 149% higher in the old ramet group than those of severed ramets, respectively, whereas they were 3.0, 3.3 and 11.2 times higher in the young ramet group, respectively. At the end of the experimental period, the shoot height, connected with young ramets, in shallow and deep water treatments increased by 19% and 26%, respectively, over that in the control treatments, whereas the old ramets increased by 11% and 39%, respectively. In contrast, the shoot height of the severed young ramets was 27% and 26% lower in shallow and deep water treatments than in the control treatment, respectively. However, the shoot height of the severed old ramets remained constant with increasing water depth. We conclude that clonal integration enhances the flood tolerance of S. alterniflora daughter ramets, and the trait of clonal integration plays more important roles in severe flooding stress conditions and at early growth stages.     

Water translocation between ramets of strawberry during soil drying and its effects on photosynthetic performance

To explore the mechanisms underlying water regulation in clonal plants and its effects on carbon assimilation under water stress, we studied the responses of water status, gas exchange and abscisic acid (ABA) contents to water stress in leaves of pairs of strawberry ramets that consist of mother and daughter ramets. There was a greater decrease in photosynthetic rates (P_n) and stomatal conductance (G_s) in the disconnected mother ramets than the connected mother ramets upon exposure to water stress, indicating that water stress in mother ramets was alleviated by water translocation from the well‐watered daughter ramets. Conversely, the connected mother ramets displayed enhanced symptoms of water stress when the connected daughter ramets were exposed to water deficit. The mother ramets had lower water potential (ψ_w) due to their stronger osmotic adjustment than in well‐watered daughter ramets; this resulted in water flow from the connected daughter ramets to mother ramets, thus alleviating water stress of mother ramets. During soil drying, there was a striking increase in ABA concentrations in leaves of the disconnected mother ramets, whereas leaf bulk ABA was much lower in the connected and water‐stressed mother ramets than that in the drought‐affected mother ramets in the disconnected group. In this study, though G_s was linearly correlated with leaf bulk ABA and ψ_w, G_s in water‐stressed mother ramets in disconnected group exhibited less sensitivity to the variation in leaf bulk ABA and ψ_w than that in connected and water‐stressed mother ramets. Taken together, these results indicate that: (1) the flux of water translocation between the connected ramets is determined by a water potential gradient; (2) water translocation between connected ramets helps to keep sensitivity of G_s to ABA and ψ_w in drought‐affected ramets, thereby benefit to effectively maintain the homeostasis of leaf water status and (3) the improvements in P_n in water‐stressed ramets due to water translocation from well‐watered ramets suggest the advantages of physiological integration in clonal plants in environments with heterogeneous water distribution.     

Clonal integration in Ranunculus reptans: by‐product or adaptation?

We studied fitness consequences of clonal integration in 27 genotypes of the stoloniferous herb Ranunculus reptans in a spatially heterogeneous light environment. We grew 216 pairs of connected ramets (eight per genotype) with mother ramets in light and daughter ramets in shade. In half of the pairs we severed the stolon connection between the two ramets at the beginning of the experiment. During the experiment, 52.7% of the ramet pairs with originally intact connection physically disintegrated. We detected significant variation among genotypes in this regard. Survival of planted ramets was 13.3% higher for originally connected pairs. Moreover, there was significant variation among genotypes in survival, in the difference in survival between plant parts developing from mother and daughter ramets, and in the effect of integration on this difference. In surviving plants connection between ramets decreased size differences between mother and daughter parts. Variation among genotypes was significant in growth and reproduction and marginally significant in the effect of physiological integration on growth and reproduction. Connected daughter ramets had longer leaves and internodes than daughters in severed pairs indicating that integration stimulated plant foraging in both the vertical and the horizontal plane. Observed effects of integration on fitness components in combination with genetic variation in maintenance and effects of connection indicate that clonal integration in R. reptans has the capability to evolve, and therefore suggest that clonal integration is adaptive. If genetic variation in integration is common, future studies on clonal integration should always use defined genetic material and many clones to allow extrapolation of results to population and wider levels.     

Effects of salinity and clonal integration on growth and sexual reproduction of the invasive grass Spartina alterniflora

The purpose of this study was to explore clonal integration of Spartina alterniflora under gradually changing substrate salinity conditions. We hypothesized that there might be a trade-off between growth and sexual reproduction influenced by soil salinity and, that clonal integration would change this trade-off. The experiment consisted of three levels of substrate salinity (5‰, 20‰ and 35‰), two clonal integration treatments (rhizomes severed or not), and three growth stages of daughter ramets (21, 40 and 60 cm tall). Both growth and sexual reproduction of S. alterniflora greatly decreased with increasing salinity. Clonal integration enhanced the survival, growth and sexual reproduction of daughter ramets experiencing salt stress, especially for young ramets, whereas the performance of mother ramets was reduced by clonal integration. Therefore, clonal integration did not affect performance of the whole clones. Contrary to expectations, there was no evidence for a trade-off between growth and sexual reproduction associated with salinity. In addition, clonal integration did not change the effect of salinity on the growth and sexual reproduction of mother and daughter ramets nor of the whole clones.     

Trade-offs among growth, clonal, and sexual reproduction in an invasive plant Spartina alterniflora responding to inundation and clonal integration

The purpose of this article was to study the trade-offs among vegetative growth, clonal, and sexual reproduction in an aquatic invasive weed Spartina alterniflora that experienced different inundation depths and clonal integration. Here, the rhizome connections between mother and daughter ramets were either severed or left intact. Subsequently, these clones were flooded with water levels of 0, 9, and 18 cm above the soil surface. Severing rhizomes decreased growth and clonal reproduction of daughter ramets, and increased those of mother ramets grown in shallow and deep water. The daughter ramets disconnected from mother ramets did not flower, while sexual reproduction of mother ramets was not affected by severing. Clonal integration only benefited the total rhizome length, rhizome biomass, and number of rhizomes of the whole clones in non-inundation conditions. Furthermore, growth and clonal reproduction of mother, daughter ramets, and the whole clone decreased with inundation depth, whereas sexual reproduction of mother ramets and the whole clones increased. We concluded that the trade-offs among growth, clonal, and sexual reproduction of S. alterniflora would be affected by inundation depth, but not by clonal integration.     

Does clonal integration improve competitive ability? A test using aspen (Populus tremuloides [Salicaceae]) invasion into prairie

Many clonal plants consist of many connected individual ramets, allowing them to share water and nutrients via physiological integration. Integration among ramets may also improve the ability of clonal plants to tolerate abiotic stress or improve the competitive ability of individual ramets. Here I use a field experiment to determine whether clonal integration improves ramet performance for a widespread clonal tree species invading into native prairie. Aspen (Populus tremuloides) dominates the southern treeline in western Canada, has long-lived belowground connections between mother and daughter ramets, and reproduces vegetatively via resprouting rhizomes after disturbance. I applied two competition treatments (neighbors present or absent) and two clonal integration treatments (belowground rhizomes between mother and daughter ramets either severed or left intact) to 12 replicate Populus daughter ramets at each of three sites. Neighbors improved the survivorship of Populus ramets by 25-35% after 2 yr, but decreased growth by ～20%. Clonal integration tended to improve ramet survival and growth, but these trends were often not significant. Clonal integration did not alter the effects of competition from neighboring vegetation, suggesting that connections between ramets do not necessarily improve the competitive ability of Populus invading into native prairie.