叶脉结构与功能及其对叶片经济谱的影响

叶脉由贯穿于叶肉内部的维管组织及其外围机械组织构成, 多样化的脉序及网络结构使叶脉系统发生变异和功能分化。该文综述了叶脉系统结构与功能的最新研究进展。通过聚焦叶脉分级系统的结构与功能及其在叶片经济谱(LES)中的重要性, 解释叶脉性状与其它叶片功能性状之间的关系及机制。不同等级叶脉在机械支撑与水分运输方面存在功能分化, 其中1-3级粗脉在维持叶片形状和叶表面积以及物理支撑方面发挥重要作用, 有利于维持叶片最大受光面积; 4级及以上细脉具有水分调节功能, 它们与气孔相互协调, 影响叶片水分运输、蒸腾散热和光合作用速率。叶片生长过程与叶脉发育的动态变化模式决定叶脉密度, 并影响叶脉密度与叶片大小之间的关系: 叶面积与粗脉密度呈显著负相关, 与粗脉直径呈显著正相关, 而与细脉密度无关。与叶脉性状相关的叶片经济谱框架模型预测, 叶脉密度较高的叶片寿命短、比叶重较小, 叶片最大碳同化速率、代谢速率以及资源获取策略潜力较高。     

Diurnal cycles of leaf extension in unsalinized and salinized Beta vulgaris

Abstract. Continuous high resolution measurement of sugar beet leaf extension over 5 d in growth chambers showed average leaf extension rates (LER) in darkness to be from three to six times those in light for plants growing in non-salinized media. The changes in LER in light-dark transitions occurred within seconds, a response which was more rapid than stomatal opening or closing. When the growth medium was salinized to 100 mol m⁻³ NaCl, LER's were reduced by about 50% in darkness and 90% in light, markedly increasing the ratio of dark to light LER.
A 2-d episode of root-zone salinity imposed midway through a 5-d period of measurement decreased LER and produced higher leaf temperatures. LER and diurnal leaf temperature patterns reverted to their pre-salinized levels when root-zone salinity was removed. Thus, the effects of short episodes of high sodium chloride in the growth medium appear to be reversible, suggesting a water stress mechanism of growth reduction rather than toxicity effects of salt.     

浙江天童常绿植物当年生与往年生叶片性状的变异与关联

植物叶片性状随叶龄的变化是植物生活史策略的体现, 反映了植物叶片的物质投资和分配方式。该研究通过在个体和物种2个水平, 比较浙江天童1 hm ²样地内常绿阔叶树种的平均叶面积(MLA)、比叶面积(SLA)和叶片干物质含量(LDMC)在当年生和往年生叶片间的差异和关联, 探究叶片物质分配策略在异龄叶间的变化, 并分析叶龄对植物叶片性状, 特别是叶片面积建成消耗的影响。结果显示: 1)在个体和物种水平上, MLA变异系数最大(个体: 79.5%; 物种: 66.5%), SLA次之(个体: 28.1%; 物种: 24.7%), LDMC较低(个体: 17.0%, 物种: 14.1%); 当年生叶片MLA、LDMC和SLA的变异系数均高于往年生叶片; 2)往年生叶MLA显著大于当年生叶(t = -38.53, p < 0.001), 往年生叶SLA显著小于当年生叶(t = 45.30, p < 0.001), 往年生叶LDMC显著大于当年生叶(t = -9.71, p < 0.001); 3)在个体水平, 当年生叶片MLA、SLA和LDMC值分别解释了往年生叶片MLA、SLA和LDMC变异的86%、48%和41%; 在物种水平, 当年生叶片MLA、SLA和LDMC值分别解释了往年生叶片MLA、SLA和LDMC变异的97%、83%和85%; 4) SLA在异龄叶间的变化表明, 与往年生叶片相比, 投资相同干物质, 当年生叶片可形成较大的叶面积, 其叶片面积建成消耗较小。研究认为, 植物叶性状在异龄叶间具有较大的变异性和关联性, 叶面积形成过程中生物量建成与消耗的协调可能影响植物叶片的发育。     

Distinct controls of leaf widening and elongation by light and evaporative demand in maize

Leaf expansion depends on both carbon and water availabilities. In cereals, most of experimental effort has focused on leaf elongation, with essentially hydraulic effects. We have tested if evaporative demand and light could have distinct effects on leaf elongation and widening, and if short‐term effects could translate into final leaf dimensions. For that, we have monitored leaf widening and elongation in a field experiment with temporary shading, and in a platform experiment with 15 min temporal resolution and contrasting evaporative demands. Leaf widening showed a strong (positive) sensitivity to whole‐plant intercepted light and no response to evaporative demand. Leaf elongation was (negatively) sensitive to evaporative demand, without effect of intercepted light per se. We have successfully tested resulting equations to predict leaf length and width in an external dataset of 15 field and six platform experiments. These effects also applied to a panel of 251 maize hybrids. Leaf length and width presented quantitative trait loci (QTLs) whose allelic effects largely differed between both dimensions but were consistent in the field and the platform, with high QTL × Environment interaction. It is therefore worthwhile to identify the genetic and environmental controls of leaf width and leaf length for prediction of plant leaf area.     

Relationships between sclerophylly,leaf biomechanical properties and leaf anatomy in some Australian heath and forest species

ABSTRACT

A previous study of 19 south-east Australian heath and forest species with a range of leaf textures showed that they varied considerably in leaf biomechanical properties. By using an index of sclerophylly derived from botanists' rankings (botanists' sclerophylly index, BSI) we determined that leaves considered by botanists to be sclerophyllous generally had both high strength and work to fracture (particularly in punching and tearing tests), both at the level of leaf and per unit leaf thickness. In the current study we have shown that leaves from the same species also varied considerably in leaf specific mass (46–251 g m^-2), neutral detergent fibre concentration (20–59% on a dry weight basis) and in leaf anatomy. Multiple regression indicated a very strong correlation between BSI and the first two components of a principal components analysis (PCA) of leaf anatomy (R ² = 0.91). In addition, there was strong correlation between the first component of a PCA of the mechanical properties (correlated with BSI) and the two axes derived from anatomical characteristics (R ² = 0.66). The anatomical properties contributing most to the significant component axes were thickness of palisade mesophyll and upper cuticle (axis 1) and percentage fibre (neutral detergent fibre) and lower epidermis thickness (axis 2). However, whether these relationships are causal, or reflect correlations with characteristics not measured in this study, such as vascularization and sclerification, is not clear. At a finer scale, however, there is evidence that there are various ways to be sclerophyllous, both in terms of anatomical and mechanical properties. This is illustrated by comparison of two of the sclerophyllous species, Eucalyptus baxteri and Banksia marginata.     

Adaxial–abaxial polarity: The developmental basis of leaf shape diversity

Leaves of flowering plants are diverse in shape. Part of this morphological diversity can be attributed to differences in spatiotemporal regulation of polarity in the upper (adaxial) and lower (abaxial) sides of developing leaves. In a leaf primordium, antagonistic interactions between polarity determinants specify the adaxial and abaxial domains in a mutually exclusive manner. The patterning of those domains is critical for leaf morphogenesis. In this review, we first summarize the gene networks regulating adaxial–abaxial polarity in conventional bifacial leaves and then discuss how patterning is modified in different leaf type categories. genesis 52:1–18, 2014. © 2013 The Authors. Genesis Published byWiley Periodicals, Inc.     

干旱区植物叶片大小对叶表面蒸腾及叶温的影响

利用热及物质交换原理, 并结合前人研究成果, 在单叶尺度上建立了简单的叶温和水气蒸腾模型。模型通过预设值驱动, 预设值参照干旱区环境及植物叶片特征设置。模拟结果显示: 随气孔阻力的增加, 叶片蒸腾速率降低, 叶温升高; 同一环境下, 具有低辐射吸收率的叶片蒸腾速率和叶温更低, 并且气孔阻力越大, 这种差异越明显。另外, 叶片宽度及风速是影响叶片蒸腾及叶温的重要因子。干旱地区植物生长季节, 风速小于0.1 m·s ^-1、气孔阻力接近1000 s·m ^-1时, 降低叶片宽度不仅有利于降低叶片温度, 而且能够降低叶片蒸腾速率, 从而实现保持水分, 增强植物适应高温、干旱的能力。     

五大连池新期火山熔岩台地3种共有植物的叶功能性状及其相互关系

以五大连池新期火山熔岩台地13个稳定的自然植物群落共有种香杨、万年蒿、岩败酱为研究对象,测定其叶干物质含量(LDMC)、比叶面积(SLA)、叶氮含量(LNC)、叶磷含量(LPC)、叶氮磷比(N/P)等叶功能性状,研究不同生境下3种植物叶功能性状的变异特征,探讨新期火山熔岩台地植物叶功能性状相互之间的内在联系及其对环境的适应性。结果表明:(1)3种植物LDMC变化在0.294~0.359g·g~(-1)之间,SLA变化在9.082~22.347m2·kg~(-1)之间;与其他区域的研究结果相比,新期火山熔岩台地植物的LDMC值相对偏大、SLA值相对偏小,说明五大连池新期火山熔岩台地的植物采用高LDMC低SLA策略适应贫瘠恶劣的环境。(2)3种植物LNC变化在9.690~15.710g·kg~(-1)之间,LPC变化在0.669~1.078g·kg~(-1)之间,叶钾含量(LKC)变化在10.410~29.830g·kg~(-1)之间,叶N/P的变化在9.781~20.990之间;与其他区域的研究结果相比,新期火山熔岩台地植物LNC和LPC值相对偏小,LKC和N/P值相对偏大,说明五大连池新期火山熔岩台地的植物生长主要受磷素的限制,而且LNC偏小和LKC偏高与新期火山熔岩台地土壤中全N、全K的含量变化特征有关。(3)通过ANVOA分析发现,群落间植物叶功能性状的变异幅度较小,3种植物之间N/P、LDMC和SLA的变异幅度也较小,这说明在水分和养分极缺的火山熔岩台地植物对其生境的适应对策相似。(4)Pearson相关分析发现,SLA与LDMC以及N/P与LDMC和SLA均呈显著负相关关系。     

A Comparison of Photosynthesis in Endangered and Non-Endangered Plants Changium smyrnioides and Anthriscus sylvestris

Changium smyrnioides Wolff. and Anthriscus sylvestris (L.) Hoffm. have similar photosynthetic characters; they use radiant energy in winter and early spring effectively, but cannot take full advantage of higher irradiance after spring. The specific leaf area (SLA), leaf area ratio (LAR), and leaf mass ratio (LMR) of C. smyrnioides were lower than those of A. sylvestris. The photosynthetic period of C smyrnioides was about 160 d shorter than that of A. sylvestris, causing the total photosynthetic production of C. smyrnioides to be lower than that of A. sylvestris. Hence if C. smyrnioides is disturbed, it could not recover within a short period.     

Determinants of some leaf characteristics of Australian mangroves

Leaf characteristics reflecting the size, lifespan (longevity), moisture content (degree of succulence) and complexity of structure of 20 mangrove species were studied over several years at 13 locations along the tropical and subtropical Australian coast. These characteristics were found to fall generally within the ranges of those for woody species from other ecosystems. With the exception of one species, it was found that leaf longevity was related inversely to leaf moisture content, increasing from nearly 6 months in more succulent species to over 2 years in less succulent species. This suggested that more succulent leaves are less complex in their structure because they have less well‐developed ability to compartmentalize salt. There was a tendency also for leaf longevity to increase in species with larger leaves. These findings were consistent with the general view for land plants that leaf longevity is greater in species that have developed tolerance to environmental stress, salt particularly in the case of mangroves. Leaf tissue in such species is more robust or complex and requires greater metabolic resources in its construction; the plant is then advantaged by retaining the tissue for longer periods. Classification of the species considered here, based on their leaf longevity, moisture content and complexity, identified phylogenetically related species groupings that reflected these leaf longevity effects.     

Hydraulic limitations imposed by crown placement determine final size and shape of Quercus rubra L. leaves

The canopies of large broad‐leaf trees exhibit significant heterogeneity in both micro‐environmental conditions and leaf morphology. Whether the visible differences in the size and shape of leaves from the top and bottom of the crown are determined prior to bud break or result from different patterns of leaf expansion is not known. Analysis of ontogenetic changes of both the degree of lobing and vein density in Quercus rubra demonstrates that leaves throughout the crown are identical in size and shape at the time of bud break. Morphological adaptation to the local micro‐environment takes place during the expansion phase and starts after the determination of the vascular architecture has been completed. Leaves from the bottom of the crown undergo greater expansion in the tissue close to the main veins than occurs either in the more peripheral tissue of the same leaf or anywhere in leaves from the top of the crown. This results in a water transport system that is well suited to the low evaporative rates near the bottom of the crown, but inadequate for the conditions found at the top of the tree. Acclimation of leaf form and function based upon differential expansion may be entirely driven by the local hydraulic demand during the expansion phase, resulting in leaf size and vein density being determined during development by the same hydraulic properties which will constrain the size of leaf that can be functionally supported at maturity.     

着生位置对水曲柳小叶性状变异及性状间相关性的影响

复叶植物相比单叶植物更具生长优势, 但复叶内部小叶性状及其相关关系是否受到着生位置影响尚未可知。该研究以东北典型复叶植物水曲柳(Fraxinus mandshurica)为研究对象, 测定复叶内部不同着生位置小叶的叶厚(LT)、叶面积(LA)、叶干物质含量(LDMC)、比叶面积(SLA)、叶氮含量(LNC)和叶磷含量(LPC), 分析上述6种小叶性状及其生长关系在复叶内部的变异, 并分别通过最小显著性差异(LSD)法以及标准化主轴(SMA)法检验着生位置对小叶性状及性状间生长关系是否存在显著影响。结果表明: (1) LT、LA、LDMC和LNC随小叶着生位置级别增加(从复叶顶端至复叶基部)呈减小趋势, 但SLA和LPC呈增大趋势。(2)复叶内部, LNC与SLA间以及LT与LDMC间表现为同速生长关系, LT、SLA、LPC 3个性状与LA间, SLA、LNC、LPC 3个性状与LDMC间以及LPC与LT间均表现为异速生长关系。(3)小叶着生位置对LA与LT、SLA、LPC之间的相关关系存在显著影响, LT、SLA与LA的斜率在三级小叶(复叶中部)附近达到最大值, LT、LPC与LA的斜率绝对值在六级小叶(复叶基部)处达到最小值。整体而言, 复叶内部小叶性状随着生位置存在一定变异规律, 小叶性状间多表现为异速生长关系, 且小叶性状间的生长关系一定程度上受着生位置的调控。     

从异龄叶性状分析几种常绿阔叶植物变异与关联

该研究从个体与物种两个水平分析福建省鬼洞山中亚热带常绿阔叶次生林中七种阔叶树种异龄叶的平均叶面积(MLA)、比叶面积(SLA)和叶干物质含量(LDMC)三个性状的变异及关联,探讨叶性状物质分配策略对植物生活策略优化的限制性影响。结果表明:(1)对七种阔叶树种的个体和物种水平变异系数而言,均为MLA(82.9%;76.9%)SLA(38.9%;35.5%)LDMC(25.4%;23.8%);在个体和物种水平上当年生叶片MLA变异系数(71.5%;64.0%)小于往年生叶片(72.2%;65.8%),SLA、LDMC值则相反。(2)在个体和物种水平,当年生叶MLA对往年生叶MLA变异的解释率分别为50.1%和61.5%,当年生叶SLA对往年生叶SLA变异的解释率分别为56.6%和77.0%,当年生叶LDMC对往年生叶LDMC变异的解释率分别为51.7%和68.3%。(3)7种亚热带常绿阔叶植物异龄叶MLA、SLA与LDMC变化规律说明,当年生叶与往年生叶投资相同干物质,当年叶可形成更大的叶面积,且叶面积建成的消耗较往年叶小。研究认为,异龄叶性状在异龄叶间存在变异与关联,叶面积形成过程中生物量建成与消耗的协调可能影响植物叶片的发育。     

Morphological and ultrastructural aspects of dehydration and rehydration in leaves of Sporobolus stapfianus

The resurrection species Sporobolus stapfianus Gandoger has been studied by LM, TEM and SEM in order to define the leaf morphology and fine structure and to analyse the cellular changes occurring during the processes of dehydration and rehydration of the plant. Some characteristics of the fully hydrated leaf and some ultrastructural and physiological events which take place during leaf wilting are discussed in relation to their possible role in plant desiccation-tolerance.The leaves of S. stapfianus show several characteristics common among xerophytic species. In the resurrection leaf they could play a role in slowing down the drying rate, thus leaving time to activate the mechanisms protecting the cell structures against drought damage. Actually, the S. stapfianus leaves do not undergo important cellular alterations during dehydration. The chloroplasts, in particular, retain part of their photosynthetic pigments and thylakoid membranes. Upon rewatering leaf recovery is rather fast and the tissue structure and cell organization of the fully hydrated state are already regained after two days.     

Leaf age and salinity influence water relations of pepper leaves

Plant growth is reduced under saline conditions even when turgor in mature leaves is maintained by osmotic adjustment. The objective of this study was to determine if young leaves from salt-affected plants were also osmotically adjusted. Pepper plants (Capsicum annuum L. cv. California Wonder) were grown in several levels of solution osmotic potential and various components of the plants' water relations were measured to determine if young, rapidly growing leaves could accumulate solutes rapidly enough to maintain turgor for normal cell enlargement. Psychrometric measurements indicated that osmotic adjustment is similar for both young and mature leaves although osmotic potential is slightly lower for young leaves. Total water potential is also lower for young leaves, particularly at dawn for the saline treatments. The result is reduced turgor under saline conditions at dawn for young but not mature leaves. This reduced turgor at dawn, and presumably low night value, is possibly a cause of reduced growth under saline conditions. No differences in leaf turgor occur at midday. Porometer measurements indicated that young leaves at a given salinity level have a higher stomatal conductance than mature leaves, regardless of the time of day. The result of stomatal closure is a linear reduction of transpiration.     

Adaptive survival mechanisms and growth limitations of small-stature herb species across a plant diversity gradient

Several biodiversity experiments have shown positive effects of species richness on aboveground biomass production, but highly variable responses of individual species. The well-known fact that the competitive ability of plant species depends on size differences among species, raises the question of effects of community species richness on small-stature subordinate species. We used experimental grasslands differing in species richness (1-60 species) and functional group richness (one to four functional groups) to study biodiversity effects on biomass production and ecophysiological traits of five small-stature herbs (Bellis perennis, Plantago media, Glechoma hederacea, Ranunculus repens and Veronica chamaedrys). We found that ecophysiological adaptations, known as typical shade-tolerance strategies, played an important role with increasing species richness and in relation to a decrease in transmitted light. Specific leaf area and leaf area ratio increased, while area-based leaf nitrogen decreased with increasing community species richness. Community species richness did not affect daily leaf carbohydrate turnover of V. chamaedrys and P. media indicating that these species maintained efficiency of photosynthesis even in low-light environments. This suggests an important possible mechanism of complementarity in such grasslands, whereby smaller species contribute to a better overall efficiency of light use. Nevertheless, these species rarely contributed a large proportion to community biomass production or achieved higher yields in mixtures than expected from monocultures. It seems likely that the allocation to aboveground plant organs to optimise carbon assimilation limited the investment in belowground organs to acquire nutrients and thus hindered these species from increasing their performance in multi-species mixtures.