999 resultados para Leaf structure
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Madeira vine (Anredera cordifolia (Ten.) Steenis) is a climber in the angiosperm family Basellaceae. It is native to South America and has naturalised in Australia. It is regarded as a serious environmental weed because of the structural damage it causes to native vegetation. The present study, for the first time, documents anatomical and morphological traits of the leaves of A. cordifolia and considers their implications for its ecology and physiology. Plants were grown under three different light levels, and anatomical and morphological leaf characters were compared among light levels, among cohorts, and with documented traits of the related species, Basella alba L. Stomata were present on both the adaxial and abaxial sides of the leaf, with significantly more stomata on the abaxial side and under high light. This may account for the ability of this species to fix large amounts of carbon and rapidly respond to light gaps. The leaves had very narrow veins and no sclerenchyma, suggesting a low construction cost that is associated with invasive plants. There was no significant difference in any of the traits among different cohorts, which agrees with the claim that A. cordifolia primarily propagates vegetatively. The anatomy and morphology of A. cordifolia was similar to that of B. alba.
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Madeira vine (Anredera cordifolia (Ten.) Steenis) is a climber in the angiosperm family Basellaceae. It is native to South America and has naturalised in Australia. It is regarded as a serious environmental weed because of the structural damage it causes to native vegetation. The present study, for the first time, documents anatomical and morphological traits of the leaves of A. cordifolia and considers their implications for its ecology and physiology. Plants were grown under three different light levels, and anatomical and morphological leaf characters were compared among light levels, among cohorts, and with documented traits of the related species, Basella alba L. Stomata were present on both the adaxial and abaxial sides of the leaf, with significantly more stomata on the abaxial side and under high light. This may account for the ability of this species to fix large amounts of carbon and rapidly respond to light gaps. The leaves had very narrow veins and no sclerenchyma, suggesting a low construction cost that is associated with invasive plants. There was no significant difference in any of the traits among different cohorts, which agrees with the claim that A. cordifolia primarily propagates vegetatively. The anatomy and morphology of A. cordifolia was similar to that of B. alba.
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Gochnatia polymorpha (Less.) Cabrera é uma espécie de Asteraceae com ampla distribuição no bioma cerrado, sendo encontrada em diversas fisionomias florestais da região sudeste do Brasil. O presente estudo descreve alguns caracteres anatômicos foliares dessa espécie e os analisa quantitativamente em função de sua ocorrência nas formações florestais e também das diferenças de luminosidade. Foram encontradas diferenças quantitativas em todos os parâmetros anatômicos analisados. Os resultados demonstram que a alta plasticidade anatômica foliar nesta espécie pode ser considerada como uma vantagem adaptativa que a permite ocorrer em diversos ambientes do cerrado.
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Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)
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Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)
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Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)
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We studied the development of leaf characters in two Southeast Asian dipterocarp forest trees under different photosynthetic photon flux densities (PFD) and spectral qualities (red to far-red, R:FR). The two species, Hopea helferi and H. odorata, are taxonomically closely related but differ in their ecological requirements; H. helferi is more drought tolerant and H. odorata more shade tolerant. Seedlings were grown in replicated shadehouse treatments of differing PFD and R:FR. We measured or calculated (1) leaf and tissue thicknesses; (2) mesophyll parenchyma, air space, and lignified tissue volumes; (3) mesophyll air volumes (Vmes/Asurf) and surfaces (Ames/Asurf); (4) palisade cell length and width; (5) chlorophyll/cm2 and a/ b; (6) leaf absorption; and (7) attenuance/absorbance at 652 and 550 nm. These characters varied in response to light conditions in both taxa. Characters were predominantly affected by PFD, and R:FR slightly influenced many characters. Leaf characters of H. odorata were more plastic in response to treatment conditions. Characters were correlated with each other in a complex fashion. Variation in leaf anatomy is most likely a consequence of increasing leaf thickness in both taxa, which may increase mechanical strength and defense against herbivory in more exposed environments. Variation in leaf optical properties was most likely affected by pigment photo-bleaching in treatments of more intense PFD and was not correlated with Amax. The greater plasticity of leaf responses in H. odorata helps explain the acclimation over the range of light conditions encountered by this shade-tolerant taxon. The dense layer of scales on the leaf undersurface and other anatomical characters in H. helferi reduced gas exchange and growth in this drought-tolerant tree.
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Gochnatia polymorpha (Less.) Cabrera is a widespread tree species found in different physiognomies of neotropical savanna (cerrado) formations of south-eastern Brazil. The present study describes some leaf anatomical characteristics of this species as a function of the time of leaf flush, during dry or wet seasons. This species presents anatomical plasticity in the cuticle, palisade parenchyma and abaxial epidermis as well as in stomatal size and stomatal and trichome density, which are leaf structures linked with water-status control. Leaf structure changed to suit the particular environmental conditions during dry and wet seasons. The production of different wet-and dry-season leaf types in G. polymorpha could be a response to drought and an adaptation to environmental constraints in the cerrado.
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The ecology of forest and savanna trees species will largely determine the structure and dynamics of the forest-savanna boundaries, but little is known about the constraints to leaf trait variation imposed by selective forces and evolutionary history during the process of savanna invasion by forest species. We compared seasonal patterns in leaf traits related to leaf structure, carbon assimilation, water, and nutrient relations in 10 congeneric species pairs, each containing one savanna species and one forest species. All individuals were growing in dystrophic oxisols in a fire-protected savanna of Central Brazil. We tested the hypothesis that forest species would be more constrained by seasonal drought and nutrient-poor soils than their savanna congeners. We also hypothesized that habitat, rather than phylogeny, would explain more of the interspecific variance in leaf traits of the studied species. We found that throughout the year forest trees had higher specific leaf area (SLA) but lower integrated water use efficiency than savanna trees. Forest and savanna species maintained similar values of predawn and midday leaf water potential along the year. Lower values were measured in the dry season. However, this was achieved by a stronger regulation of stomatal conductance and of CO2 assimilation on an area basis (A area) in forest trees, particularly toward the end of the dry season. Relative to savanna trees, forest trees maintained similar (P, K, Ca, and Mg) or slightly higher (N) leaf nutrient concentrations. For the majority of traits, more variance was explained by phylogeny, than by habitat of origin, with the exception of SLA, leaf N concentration, and A area, which were apparently subjected to different selective pressures in the savanna and forest environments. In conclusion, water shortage during extended droughts would be more limiting for forest trees than nutrient-poor soils. © 2013 Springer-Verlag Berlin Heidelberg.
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Deciduous forests from the neotropics are one of the most endangered forest types in the world due to the exploitation of their natural resources by mankind. Many aspects of these ecosystems have been studied; however, there is a lack of information about leaf structure and the effects of tree dominance on their structural leaf patterns. In this article, we examine leaf anatomy and specific leaf areas (SLA) in 13 tree species differing in their dominance in a Dry Forest site in Central Brazil, relating leaf anatomical traits with phytosociological aspects. Leaf anatomical traits differed according to tree dominance: greater leaf thickness (achieved through greater thickness of the mesophyll), low values of SLA and bigger stomata were found for the most dominant species, whereas the less dominant species showed thinner leaves with high SLA, as well as numerous and small stomata. These responses suggest that tree dominance is an important indirect effect associated with vertical light availability in the forest. These strategies are probably related to the accomplishment of a high performance in carbon gain and water economy, given the distinction in irradiance that the leaves of different species are subject to in the dry forest. © 2013 Copyright The Royal Society of New Zealand.
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Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)
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Quilpie mesquite (Prosopis velutina) is an invasive woody weed that is believed to have been introduced into south-west Queensland in the 1930s. Following the withdrawal of 2,4,5-T, research on P. pallida resulted in revised recommendations for control of all Prosopis spp. in Queensland. Adoption of many of these recommendations for Quilpie mesquite control produced substandard results. Following a pilot trial, a shade-house experiment was conducted to determine the differences in susceptibility of two species of mesquite, P. velutina and P. pallida, to commonly available herbicides. It was hypothesized that P. velutina was less susceptible than P. pallida, based upon claims that the registered chemical recommendations for Prosopis spp. were not sufficiently effective on P. velutina. Nine foliar herbicide treatments were applied to potted shade-house plants. Treatment effects indicated differing susceptibility between the two species. P. velutina consistently showed less response to metsulfuron, fluroxypyr, 2,4-D/picloram and triclopyr/picloram, compared to the glyphosate formulations, where negligible differences occurred between the two species. The response to glyphosate was poor at all rates in this experiment. Re-application of herbicides to surviving plants indicated that susceptibility can decrease when follow-up application is in autumn and the time since initial application is short. The relationship between leaf structure and the volume of spray adhering to a plant was assessed across species. The herbicide captured by similar-sized plants of each species differed, with P. pallida retaining a greater volume of herbicide.
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Resurrection plants can withstand extreme dehydration to an air-dry state and then recover upon receiving water. Tripogon loliiformis (F.Muell.) C.E.Hubb. is a largely uncharacterised native Australian desiccation-tolerant grass that resurrects from the desiccated state within 72 h. Using a combination of structural and physiological techniques the structural and physiological features that enable T. loliiformis to tolerate desiccation were investigated. These features include: - (i) a myriad of structural changes such as leaf folding, cell wall folding and vacuole fragmentation that mitigate desiccation stress; - (ii) potential role of sclerenchymatous tissue within leaf folding and radiation protection; - (iii) retention of ~70% chlorophyll in the desiccated state; - (iv) early response of photosynthesis to dehydration by 50% reduction and ceasing completely at 80 and 70% relative water content, respectively; - (v) a sharp increase in electrolyte leakage during dehydration, and; - (vi) confirmation of membrane integrity throughout desiccation and rehydration. Taken together, these results demonstrate that T. loliiformis implements a range of structural and physiological mechanisms that minimise mechanical, oxidative and irradiation stress. These results provide powerful insights into tolerance mechanisms for potential utilisation in the enhancement of stress-tolerance in crop plants.
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毛乌素沙地处于鄂尔多斯生态过渡带,在生态学研究上具有重要的理论与实践意义。在这样一个典型的半干旱区,水分是影响生态系统功能的最主要的限制因子,在沙基质土壤条件下,灌木得到充分发育,而乔木及草本植物则处于相对次要的地位。由于自然植被的初级生产力主要由灌木形成,故对于灌木在生态系统中的功能的系统研究是十分重要的,但目前又未得到应有重视。在荒漠化防治当中,这一点显得尤其急迫。此外,为了较好地预测该地区生态系统对全球气候变化的响应模式,急需要建立对主要乡土灌木功能型的划分方案。本研究运用植物生理生态学的方法,从植物的结构与功能的统一性出发,探讨了上述若干问题。主要结果与结论如下: 1.讨论了气候及土壤基质作为基本的环境背景,对沙生灌木生态功能的塑造作用,尤其探讨了若干土壤物理特性与植物水分利用的关系问题。 2.光学显微解剖及电子显微镜的观察表明,在自东南至西北横贯毛乌素沙地的水分梯度上生长的灌木当中,存在鲜明的叶片结构与功能特征与水分胁迫程度之间的对应性,在自东南向西北随干旱胁迫强度的增加,灌木的旱生结构也明显增加,甚至于在鄂尔多斯西部可以见到不少超旱生植物。同时,对灌木水分关系的研究支持了以解剖学观察为基础的认识,即:不同的景观条件下,也存在灌木的抗旱性与其生长的土壤的水分可利用性之间的对应性。这显示了水分因素在灌木的生态功能发挥中所起的主导作用。 3.通过分析沙丘的水分平衡,得到如下认识:(1)沙地条件的蒸发散主要来自植物的蒸腾作用,而土壤蒸发只占10%稍多:(2)沙地凝结水对灌木的水分需求而言微乎其微:(3)对多数沙生灌木而言,适宜的种植密度应为30-40%,即相当于半固定沙丘的覆盖度。 4.在上述三点的基础上,探讨了在不同类型的干旱(气候干旱、基质干旱及生理干旱)影响下,灌木在种类组成及干旱适应对策方面的多样性,将毛乌素沙地的灌木概括为两个功能类型:(1)干旱忍耐者;(2)竞争消费者。上述将极其多样的灌木物种在水分生态功能的相似性这个层面上概括成较少的类别的偿试,可望促使该地区的灌木生态学基础研究走向深入。 5.本研究对个别灌木的生态特性的新认识: ● 关于沙地柏(Sabina vulgaris):(1)现已知道其蒸腾速率极低,本研究进一步认识到,低的蒸腾速率主要来自于气孔在叶表面上局限性分布:(2)该灌木虽十分抗旱,但过大的密度常引起叶片水分亏缺,在其根系不能利用地下潜水时.叶片水分亏缺更严重。 ● 关于油蒿(Artermisia.ordosica)及籽蒿(Asphaerocephala):现已广泛地观察到,这两种灌木在沙丘演替不同阶段呈不同的优势分布:籽蒿主要生长于流动性沙丘(这里水分条件往往很好),但随沙丘逐渐被固定,就会被油蒿取代。本研究从叶片结构与功能两方面解释了上述现象,主要依据是(l)籽蒿比油蒿往往有更大的蒸腾速率:(2)籽蒿叶片近轴面1/3以下处有极为密集的气孔分布,而在油蒿却未发现;(3)籽蒿具有极其高的零膨压时的渗透势值(ψлp)。 ● 关于蒙古岩黄芪(Hedysarum mongolicum):该灌木具有独特的 干旱适应方式(如,幼茎 可行光合作用,及叶片富含粘液细胞),但本研究提示,该灌木的抗旱性是较弱的(相比与其它同生境下的灌木而言)。主要依据是:(1)很高的零膨压时的渗透势值;(2)海绵与栅栏组织均有较充分的发育。 ● 关于沙柳(Salix psammophila):在沙基质中有广泛的适应性, 但其适应主要体现在形态上(根茎比)的可塑性,而在生理(尤其是蒸腾作用)方面的调整则不十分显著。生长于丘顶的沙柳具有极其发达的根系,这可减缓土壤水分不足对植物的不利影响;生长于丘间低地的沙柳具有好的水分供给,但在特定的微生境下,其叶片温度比生长лллл于丘顶的沙柳叶片高,尤其是在强的光照条件下,其叶片温度会大幅度升高。这有可能对植物形成不利的影响。
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为了研究高原植物对青藏高原特殊环境的适应机制,本文选取青藏高原高寒草原优势物种紫花针茅和青藏苔草作为研究物种,运用数量分析的方法对它们的形态结构及生态适应性进行了研究。试图通过对环境因子和这些形态结构变化之间的关系进行分析以找出这两种植物是如何适应严酷的环境以及这两种具有不同克隆生长方式的植物是否具有不同的适应机制。 2004年8月,我们沿青藏公路设置一条从西大滩到羊八井的样带,并进行取样。样带的生态特征从南到北变化较大:海拔从4586m上升到4901m,生长季降水量从384.0cm下降到202.2cm,生长季月均温从5.1℃下降到1.4℃,生长季月均相对湿度从65%,下降到54%,生长季蒸发量从1242cm下降到798cm,生长季月均风速从2.4m/s增大到4.0m/s。将采集的植物叶片材料制成石蜡切片,采用番红固绿对染,在显微镜下观察测量。同时研究了青藏苔草的根茎特征。数据分析中运用了变异系数比较,多重比较,相关分析和回归分析被用来分析结构变化及其与生态因子的关系。 结果表明,两物种的叶片结构特征在不同环境中的种群间存在显著差异。总体上,青藏苔草的保护组织、光合组织以及综合指标变异系数明显大于紫花针茅的,仅输导组织相关指标的变异系数小于紫花针茅的。这些结果表明,在叶片结构水平上青藏苔草比紫花针茅具有较大的可塑性,也意味着青藏苔草对生态因子变化的潜在适应能力可能较紫花针茅强。 紫花针茅和青藏苔草的大部分叶片结构特征与其生存环境的生态因子间存在着线性回归关系:紫花针茅叶肉细胞大小随土壤有效K含量增高而减小;下表皮厚度和韧皮部面积随生长季云盖度增高而增大;单一导管半径和导管平均面积随生长季月均湿度的增加而增大;青藏苔草上表皮细胞厚度随生长季月均最低温的降低而增厚;泡状细胞厚度随大陆度的增强而增加;上表皮细胞大小随土壤pH的增大而增大;导管总数和韧皮部面积随土壤速效P含量的增高而增加;气腔总面积随土壤有效K含量增高而增大。 青藏苔草分枝方式为典型的合轴分枝。分株间由埋藏在地下的匍匐根状茎连接,其扩展方式不呈直线形。青藏苔草喜沙质土,其根茎一般分布在沙土中10cm以下,在部分通气性能良好的风成沙丘或沙地,深度可超过50cm,间隔子长度依生境的不同而变化很大,短的仅约3cm,而长的可达2m多。 青藏苔草的间隔子长度和节间长度随有效温度的增加而减小,根茎每间隔子节间数随降水的增加而减少,在较低有效温度下和较低水分供给的情况下单位面积分布的克隆分株数量较少,在较高有效温度下和较高水分供给的情况下单位面积的克隆分株数量分布较多。这种变化趋势有助于青藏苔草有效迅速地占领条件适合的生境,充分利用生境内的各种资源,扩大种群;在不利条件下,青藏苔草则减少单位面积内克隆分株的分布,以适应不良生境。
