8种木本植物木质部栓塞变化与生理生态指标关系的研究Ⅰ.与植物木质部水势的关系

以自然状况下生长良好的耐旱树种刺槐(Robinia pseudoacacia L.)、元宝枫(Acer truncatum Bge.)、沙棘(Hippophae rhamnoides L.)、白榆(Ulmus pumila L.)、油松(Pinus tabulaeformis Carr.)、白皮松(Pinus bungeana Zucc.ex Endl.)及中生树种女贞(Ligustrum lucidum Ait.)、柳树(Salix matsudana Koidz. f. pendula Schneid.)为研究对象,用压力室法测定木质部水势,用冲洗法测定木质部栓塞程度,研究不同生长季节木质部栓塞与水势间的关系.结果表明针叶树油松、白皮松在各季节水势均较高,水势变化幅度较小,木质部不易发生栓塞,这与其木质部由管胞构成,对木质部栓塞不敏感,在干旱时采用高水势延迟脱水的耐旱策略有关.阔叶树刺槐、元宝枫、沙棘、白榆、女贞和柳树的木质部栓塞现象是其在每天正常生长过程中不可避免的 "平常事件",是它们适应干旱的一种方式.它们的木质部栓塞程度与水势表现出了相反的变化趋势,即同一树种在同一季节内水势值越低,木质部栓塞程度越大,但在不同树种及同一树种的不同季节不存在这种关系.由此可见,植物木质部栓塞对水势的敏感程度(即木质部栓塞脆弱性)主要由树种的木质部结构决定,同时受到树种特性、树木生长发育时期、外界环境因子的影响,木质部栓塞的脆弱性也具有季节变化特征.     

8种木本植物木质部栓塞变化与生理生态指标关系的研究 I.与植物木质部水势的关系

以自然状况下生长良好的耐旱树种刺槐（Robinia pseudoacacia L.）、元宝枫（Acer truncatum Bge）、沙棘（Hippophae rhamnoides L.）、白榆（Ulmus pumila L.）、油松（Pinus tabulaeformis Carr.）、白皮松（Pinus bungeana Zucc.ex Endl.）及中生树种女贞（Ligustrum lucidum Ait.）、柳树（Salix matsudana Koidz.f.pendula Schneid.）为研究对象,用压力室法测定木质部水势,用冲洗法测定木质部栓塞程度,研究不同生长季节木质部栓塞与水势间的火系。结果表明：针叶树油松、白皮松在各个季节水势均较高,水势变化幅度较小,木质部不易发生栓塞,这与其木质部由管胞构成,对木质部栓塞不敏感,在干旱时采用高水势延迟脱水的耐旱策略有关。阔叶树刺槐、元宝枫、沙棘、白榆、女贞和柳树的木质部栓塞现象是其在每天正常生长过程中不可避免的“平常事件”,是它们适应干旱的一种方式。它们的木质部栓塞程度与水势表现出了相反的变化趋势,即同一树种在同一季节内水势值越低,木质部栓塞程度越大,但在不同树种及同一树种的不同季节不存在这种关系。由此可见,植物木质部栓塞对水势的敏感程度（即木质部栓塞脆弱性）主要由树种的木质部结构决定,同时受到树种特性、树木生长发育时期、外界环境因子的影响,木质部栓塞的脆弱性也具有季节变化特征。     

6个耐旱树种木质部结构与栓塞脆弱性的关系

木质部栓塞脆弱性对干旱响应的研究已成为全球气候变化背景下的热点和重要内容。该文以6个耐旱树种刺槐(Robinia pseudoacacia)、沙棘(Hippophae rhamnoides)、榆树(Ulmus pumila)、元宝枫(Acer truncatum)、旱柳(Salix matsudana)、榛(Corylus heterophylla)为研究对象, 采用Cochard Cavitron离心机技术建立木质部栓塞脆弱曲线, 计算木质部栓塞脆弱性, 利用染色法、硅胶注射法等测定木质部导管直径、导管内径跨度、导管连接度、导管密度、导管长度和木质部密度, 探究木质部结构与栓塞脆弱性的关系, 区分6个耐旱树种木质部结构在抗栓塞性上的差异, 以期建立6个耐旱树种在木质部结构方面的抗栓塞性指标。结果表明: 6个耐旱树种木质部栓塞脆弱性大小为刺槐>榆树>沙棘>旱柳>元宝枫>榛, 其中, 刺槐、沙棘和榆树的栓塞脆弱曲线为“r”形, 而元宝枫、旱柳和榛的栓塞脆弱曲线为“s”形, 脆弱曲线为“r”形的树种与脆弱曲线为“s”形的树种栓塞脆弱性差异极显著(p < 0.01)。线性分析表明: 木质部结构影响各树种的栓塞脆弱性, 其中, 木质部密度影响最大(t = 0.702), 导管直径次之(t = 0.532), 导管长度影响最小(t = 0.010)。     

木本植物木质部栓塞脆弱性研究新进展

木质部空穴化和栓塞是木本植物在干旱等条件下遭受水分胁迫时产生的木质部输水功能障碍, 在全球气候变化的大背景下, 栓塞脆弱性对干旱响应的研究已成为热点和重要内容。近年来有关木质部栓塞脆弱性与植物输水结构和耐旱性的关系已有大量研究并取得一定成果, 但是, 不同学者在不同地区对不同材料的研究结果存在很大不同。该文就近年来这一研究领域取得的成果及争议问题进行了概括和总结, 主要涉及木质部栓塞脆弱性(P₅₀)及脆弱曲线的建立方法、木质部栓塞脆弱性与木质部结构(导管直径、导管长度、纹孔膜、木质部密度、纤维及纤维管胞)间的关系和木质部栓塞脆弱性与耐旱性的关系, 并对未来工作进行展望, 提出在未来的工作中应对同一树种使用Cochard Cavitron离心机法、Sperry离心机技术与传统方法建立的脆弱曲线进行比较验证、计算P₅₀值、分析植物个体器官水平差异(根、茎、叶)、测定树种生理生态指标, 探索植物栓塞脆弱性与输水结构和耐旱性的关系, 从而评估不同类型植物在未来气候变化下的耐旱能力。     

干旱胁迫下毛白杨和元宝槭的水力学调控

毛白杨(Populus tomentosa)和元宝槭(Acer truncatum)是华北平原人工林的主要树种, 研究两者水力结构和干旱-复水过程中茎非结构性碳水化合物(NSC)含量动态, 可揭示其水力学调控策略, 为全球气候变化背景下华北人工林水分平衡的科学管理提供理论依据。该研究以相同生境下分布的毛白杨和元宝槭幼树为研究材料, 测量两者的茎抗栓塞能力与水力安全阈、水力面积、叶膨压损失点等水力结构参数; 开展干旱-复水实验, 测定茎NSC含量动态以及干旱胁迫解除后复水阶段的木质部栓塞修复能力。结果表明: 毛白杨导水率损失50%对应的水势(-1.289 MPa)高于元宝槭(-2.894 MPa), 且膨压损失点时的渗透势低, 水力安全阈小, 木材密度小, 气孔调节偏向于变水行为, 表现为易栓塞的低水势忍耐脱水耐旱特性, 水分调节对策趋于冒险; 元宝槭则倾向于不易栓塞的高水势延迟脱水耐旱特性, 水分调节对策趋于保守。在干旱-复水实验中, 毛白杨可溶性糖、淀粉和茎NSC含量先减后增, 元宝槭则先增后减; 并且毛白杨表现出比元宝槭更高的栓塞修复能力, 这与植物体内茎NSC含量变化差异具有一定联系。毛白杨较高的栓塞修复能力也为其易栓塞的低水势忍耐脱水耐旱特性及冒险的水分调节对策提供水力安全保障。两树种在水力学调控上表现出的较大差异可能与其生活史特性相关。     

六种木本植物木质部栓塞化生理生态效应的研究

对６个树种１年生枝木质部栓塞及水势进行了１４个月的连续观测。测定结果表明,木质部栓塞化直接引起木质部导水率下降,从而对树木生长发育节律造成影响。对导水率的影响可通过脆弱曲线看出,６种落叶阔叶树的２类脆弱曲线模型建立：ｙ＝ａｅｂ／ｘ和ｙ＝ｘ＾２／（ａ＋ｂｘ＾２）。通过模型求解,探讨和确定了参数ａ、ｂ的生理生态学意义,并据此比较不同树种木质部栓塞脆弱性的大小,结果为沙棘＞刺槐≥白榆＞加杨＞榛木＞元宝枫     

祁连山水源区主要树种耐旱性研究

应用P-V技术对祁连山水源涵养林主要树种水分参数进行测定分析.结果表明,不同水分参数在树种上的变化规律各异,反映了植物耐旱机理的复杂性;对10项水分参数的主成分分析结果显示,以|φπ₁₀₀-φπ₀ |、RCV、ROWC₀和ε_max分析植物的耐旱性能具有可靠性.用两种几何数学方法的分析结果表明,按照耐旱性大小可将供试树种分为耐旱性强树种(青海云杉和千里香杜鹃)、耐旱性较强树种(祁连圆柏、烈香杜鹃、头花杜鹃和青海杜鹃)、耐旱性较弱树种(金露梅、绣线菊和红桦)和耐旱性弱树种(青杨).苗木清晨叶水势与土壤含水率间变化趋势可以用双曲线方程、幂函数式(或指数函数式)取得满意的拟合.通过逐步聚类分析,按照树种主要耐旱机理可分为高水势延迟脱水耐旱树种(红桦和青海杜鹃)、亚高水势延迟脱水型树种(青海云杉、千里香杜鹃和头花杜鹃)、亚低水势忍耐脱水耐旱树种(祁连圆柏)与低水势忍耐脱水型耐旱树种(金露梅、绣线菊和烈香杜鹃).     

桂西南喀斯特季雨林木本植物的水力安全

桂西南喀斯特地区生物多样性丰富、特有种多, 同时也是石漠化问题较为严重的区域。由于该喀斯特地区土层浅薄、岩石裸露、表层储水能力差, 植物在干旱季节经常会受到水分胁迫。植物水力学特征不仅是探讨喀斯特地区植物的生理生态适应性的关键, 还能够为石漠化地区的植被恢复提供重要参考。该研究测定了桂西南喀斯特季雨林17种代表性木本植物(包括不同生活型、叶片习性和生境)的木质部脆弱性曲线、最低水势、叶片膨压丧失点和边材密度等水力性状, 结果发现: (1)喀斯特植物木质部导水率丧失50%时的水势值(P₅₀)的种间差异较大(-0.51- -2.51 MPa), 其中常绿种的抗栓塞能力比落叶种强; (2)喀斯特植物的木质部水力安全边界值(最低水势与P₅₀之间的差值)的均值为0.36 MPa, 说明喀斯特森林植物在自然最低水势状况下木质部发生栓塞的程度较高; 但是不同植物种间存在显著差异, 这可能与喀斯特峰丛洼地生境的复杂性以及物种不同的抗旱策略有关; (3)由于喀斯特植物水分适应机制的多样化, 导致木质部水力安全边界与叶片膨压丧失点、边材密度的相关性并不显著。在区域气候干热化的背景下, 结合喀斯特植物的栓塞脆弱性和长期水势监测(尤其极端干旱事件)分析它们的水力安全, 对预测未来喀斯特森林物种分布和群落动态具有重要的指示作用。     

不同水分条件下两个树种木质部栓塞对P素添加的响应

 在两种水分供给(干旱胁迫和适宜水分,土壤含水量分别为田间持水量的30%～40%和70%～80%)下,研究了耐旱树种元宝枫(Acer truncatum)和 中生树种女贞(Ligustrum lucidum )木质部栓塞(以导水率(Percentage loss of hydraulic conductivity, PLC)损失程度衡量)对P素添加的 响应。结果发现,两个树种PLC的日变化均呈现出先上升后降低的规律,表明木质部栓塞的形成与恢复是植物体的一种平常事件;除适宜水分条 件的女贞外,P素可以显著提高元宝枫和遭受干旱胁迫时女贞的PLC;两种水分条件下,干旱胁迫时元宝枫木质部栓塞明显高于适宜水分供给时 。女贞的PLC在两种水分状况下无显著差异;树种间,干旱胁迫促进了元宝枫木质部的栓塞形成,明显高于同等水分条件下的女贞。该研究结果 证实了“木质部限流耐旱假设”。     

植物木质部栓塞测定技术的研究进展

气候变化引发干旱频度和强度的变化影响植物的生长发育和生态适应。干旱胁迫会引起木质部栓塞并造成水力失效,而如何准确量化木质部抗栓塞的能力对研究植物对干旱的响应过程尤为重要。通常可通过脆弱性曲线量化木质部抗栓塞的能力。目前已经研发出构建木质部栓塞脆弱性曲线的多种方法,但不同方法往往产生不一致的结果。深入理解这些方法的设计原理并在实际应用时比较各方法的异同,对合理解释相关文献数据及准确选择干旱预测模型等尤为重要。本文阐述了自然干燥法、离心法、注气法、声学测定法、同步加速器与X射线显微断层扫描法、光学可视化法及抽气法7种测定木质部栓塞脆弱性的方法,并总结了近年来各测定方法在具体研究中的运用情况及存在的争议。最后,对未来研究测定木质部栓塞脆弱性与实际运用相关方法的选择等提出了展望。     

Vulnerability to xylem embolism as a major correlate of the environmental distribution of rain forest species on a tropical island

Increases in drought‐induced tree mortality are being observed in tropical rain forests worldwide and are also likely to affect the geographical distribution of tropical vegetation. However, the mechanisms underlying the drought vulnerability and environmental distribution of tropical species have been little studied. We measured vulnerability to xylem embolism (P₅₀) of 13 woody species endemic to New Caledonia and with different xylem conduit morphologies. We examined the relation between P₅₀, along with other leaf and xylem functional traits, and a range of habitat variables. Selected species had P₅₀ values ranging between ?4.03 and ?2.00 MPa with most species falling in a narrow range of resistance to embolism above ?2.7 MPa. Embolism vulnerability was significantly correlated with elevation, mean annual temperature and percentage of species occurrences located in rain forest habitats. Xylem conduit type did not explain variation in P₅₀. Commonly used functional traits such as wood density and leaf traits were not related to embolism vulnerability. Xylem embolism vulnerability stands out among other commonly used functional traits as a major driver of species environmental distribution. Drought‐induced xylem embolism vulnerability behaves as a physiological trait closely associated with the habitat occupation of rain forest woody species.     

A review of new research progress on the vulnerability of xylem embolism of woody plants

Xylem cavitation/embolism is the blockage of xylem conduits when woody plants suffer from water stress under drought and other environmental conditions, the study of embolism has become a hot and key topic under global climate change. Recent researches on the relationship between the vulnerability of xylem embolism and hydraulic architecture/drought tolerance have made some progress, however, scholars reached different conclusions based on results from different regions or different materials. This paper reviews the current achievements and controversial viewpoints, which includes indicator of xylem embolism vulnerability (P₅₀), method of vulnerability curve establishment, the relationship between embolism vulnerability and hydraulic architecture (vessel diameter, vessel length, pit area, wood density, fiber and fiber tracheid) and the relationship between embolism vulnerability and drought tolerance of woody plants. Future studies should use Cochard Cavitron centrifuge and Sperry centrifuge coupled with traditional methods to establish vulnerability curves, calculate P₅₀, analyze the difference among different organisms (root, stem, leaf), and measure physiological and ecological indexes. Future studies should be aimed to explore the relationship between the vulnerability of xylem embolism and hydraulic architecture/drought tolerance and to assess drought tolerance ability of different species under future climate change.     

Is desiccation tolerance and avoidance reflected in xylem and phloem anatomy of two coexisting arid‐zone coniferous trees?

Plants close their stomata during drought to avoid excessive water loss, but species differ in respect to the drought severity at which stomata close. The stomatal closure point is related to xylem anatomy and vulnerability to embolism, but it also has implications for phloem transport and possibly phloem anatomy to allow sugar transport at low water potentials. Desiccation‐tolerant plants that close their stomata at severe drought should have smaller xylem conduits and/or fewer and smaller interconduit pits to reduce vulnerability to embolism but more phloem tissue and larger phloem conduits compared with plants that avoid desiccation. These anatomical differences could be expected to increase in response to long‐term reduction in precipitation. To test these hypotheses, we used tridimensional synchroton X‐ray microtomograph and light microscope imaging of combined xylem and phloem tissues of 2 coniferous species: one‐seed juniper (Juniperus monosperma) and piñon pine (Pinus edulis) subjected to precipitation manipulation treatments. These species show different xylem vulnerability to embolism, contrasting desiccation tolerance, and stomatal closure points. Our results support the hypothesis that desiccation tolerant plants require higher phloem transport capacity than desiccation avoiding plants, but this can be gained through various anatomical adaptations in addition to changing conduit or tissue size.     

Xylem embolism and stomatal regulation in two rubber clones (<Emphasis Type="Italic">Hevea brasiliensis</Emphasis> Muell. Arg.)

Vulnerability to water-stress-induced embolism of stems, petioles, and leaf midribs was evaluated for two rubber clones (RRIM600 and RRIT251). The xylem conduits were relatively vulnerable to cavitation with 50% of embolism measured for xylem pressures between –1 and –2 MPa. This feature can be related to the tropical-humid origin of the species. A distinct basipetal gradient of vulnerability was found, leaf midribs being the least vulnerable. Substantial variation in vulnerability to cavitation was found between the two clones only at the petiole level. A correlation was found between the stomatal behavior and the development of cavitation. Stomata were nearly closed when the xylem pressure reached the point of xylem dysfunction. Stomata may thus contribute to controlling the risk of cavitation. However, for one clone a poor correlation was found between stomatal regulation and petiole vulnerability. This was consistent with a high degree of embolism measured in the petioles after a soil drought event. Therefore, xylem cavitation might represent a promising criterion to evaluate the performance of rubber clones under drought conditions.     

三个耐旱树种木质部栓塞化的脆弱性及其恢复能力

植物在长期适应赖以生存的自然环境中 ,形成了一套最适宜自身生长发育的生理生态行为 ,采取各种方式来抵御或忍耐水分胁迫的影响。如通过具有深广而茂密的根系格局来保持水分吸收 ,通过气孔调节、角质层障碍作用和小的叶蒸发表面来减少水分散失 ,通过渗透调节和增加组织弹性来保持膨压 ,通过增强原生质耐脱水能力来免受伤害或少受伤害等等。植物遭受干旱危害时 ,首先出现表型反应的多是植物的叶片 ,因此 ,研究植物的耐旱机理多从叶入手 ,对根系类型、分布及根茎比在植物耐旱性方面也有不少报道[1,2 ],而对木质部在干旱适应性反应方面的研究…     

Cavitation resistance of peduncle,petiole and stem is correlated with bordered pit dimensions in Magnolia grandiflora

Variation in resistance of xylem to embolism among flowers, leaves, and stems strongly influences the survival and reproduction of plants. However, little is known about the vulnerability to xylem embolism under drought stress and their relationships to the anatomical traits of pits among reproductive and vegetative organs. In this study, we investigated the variation in xylem vulnerability to embolism in peduncles, petioles, and stems in a woody plant, Magnolia grandiflora. We analyzed the relationships between water potentials that induced 50% embolism (P₅₀) in peduncles, petioles, and stems and the conduit pit traits hypothesized to influence cavitation resistance. We found that peduncles were more vulnerable to cavitation than petioles and stems, supporting the hypothesis of hydraulic vulnerability segmentation that leaves and stems are prioritized over flowers during drought stress. Moreover, P₅₀ was significantly correlated with variation in the dimensions of inter-vessel pit apertures among peduncles, petioles and stems. These findings highlight that measuring xylem vulnerability to embolism in reproductive organs is essential for understanding the effect of drought on plant reproductive success and mortality under drought stress.