水杨酸对莴苣初生根侧根原基的形成和根内激素含量的影响

10-6mol·L-1的水杨酸(SA)处理莴苣幼苗初生根36h,可促进侧根原基形成,与生长素配合处理,则有加合效应。     

甲哌Weng对棉花幼苗侧根发生的诱导效应和机理研究

以陆地棉(Gossypium hirsutum L.)中棉所16和中棉所29号为试验材料,用垂直板培养法试验结果表明400 mg*L-1 甲哌钅翁(DPC)浸种处理显著促进棉花侧根发生,侧根原基发生量、发育速度和发生区长度都显著增加.去除侧根后,DPC增加侧根原基发生量和发育速度.在低温逆境情况下,DPC显著促进侧根发生,对增加抗低温能力有利.DPC处理提高了幼苗主根中部生长素、玉米素及其核苷含量,可能是诱导侧根发生的内在原因.     

灰叶胡杨根蘖繁殖的形态解剖学特征

利用常规石蜡切片法对灰叶胡杨(Populus pruinosa)根蘖繁殖特性进行形态解剖学研究。结果表明: 灰叶胡杨横走侧根由周皮、次生维管组织和四原型的初生木质部构成, 具有次生维管组织中维管射线、次生韧皮薄壁组织发达的结构特征。灰叶胡杨的根蘖繁殖源于横走侧根上不定芽的发生及生长发育。不定芽起源于横走侧根的木栓形成层, 木栓形成层经细胞分裂活动形成不定芽原基, 不定芽原基细胞分裂和生长分化形成在横走侧根表面可观察到的不定芽, 进而生长发育为根蘖苗。不定芽的发生具有同步或非同步的时间特征和单点或多点聚集的空间分布特点, 在生长发育过程中其基部可以产生新的不定芽。不定芽发生、分布和生长特点是根蘖苗大小不一、密集丛生的内在原因, 表明灰叶胡杨具有较强的根蘖繁殖能力。     

植物侧根发育的研究进展

侧根是植物根系的重要组成部分,其发生和发育受到内源植物激素和外界环境因素的共同影响。生长素在侧根发生起始、侧根原基的发育和侧根突破母体表皮等阶段均发挥关键作用。研究侧根的发育和形态解剖结构以及信号调控途径等,都具有重要的理论和实践意义。本文结合近年来的研究进展,综述了拟南芥和水稻侧根发育的详细过程和影响因素,重点关注生长素在侧根原基发生和发育过程中的作用。     

侧根的发生及其激素调控

本文概述了侧根发生及其植物激素调控的研究进展。侧根的发生起源于特定的中柱 鞘细胞,其发生过程可简单地分为侧根发生的起始、侧根原基的形成、侧根分生组织的形成和活化等几个关键时期。参与侧根发生调控的植物激素主要是生长素,它影响到侧根发生过程的各个时期。茉莉酸对侧根的发生也有一定的调控作用。     

侧根的发生及其激素调控

本文概述了侧根发生及其植物激素调控的研究进展。侧根的发生起源于特定的中柱鞘细胞,其发生过程可简单地分为侧根发生的起始、侧根原基的形成、侧根分生组织的形成和活化等几个关键时期。参与侧根发生调控的植物激素主要是生长素,它影响到侧根发生过程的各个时期。茉莉酸对侧根的发生也有一定的调控作用。     

ABA对植物侧根发生的调节(综述)

本文概述侧根发生及其受ABA调控的研究进展.ABA通过抑制部分侧根起始基因的表达、抑制侧根分生组织的活化等调控侧根发生.氮水平和干旱胁迫抑制拟南芥侧根发育,ABA可以缓解这种抑制作用.ABA和生长素在侧根原基发生过程中相互作用,其作用机理较为复杂.     

核桃试管不定根的组织学研究

以核桃品种‘新早丰’试管嫩茎为试材,采用二步生根法诱导生根,对其试管苗不定根发生发育过程进行了解剖学研究。结果表明:核桃试管嫩茎内未发现潜伏根原基;诱导生根后,不定根原基起源于形成层,特别是髓射线正对的形成层部分,属于诱生根原基型;不定根上的侧根起源于中柱鞘细胞。核桃试管嫩茎不定根的发育过程可分为4个阶段:(1)形成层细胞分裂;(2)转变为分生组织细胞群(即根原始细胞);(3)细胞群发育成可见的根原基; (4)根原基内细胞继续分裂分化形成根尖的外形,其内发育出维管束,并向外生长,穿过皮层,突破茎表皮。在组织培养条件下长出的不定根内部解剖构造为典型的初生构造,移栽后68 d出现次生构造。另外,试管苗根毛出现与否及其发育状况受基质理化性质的影响,即生态条件可以改变组织发生及其形状。     

8-甲氧基二氢血根碱化感潜能的评估

以莴苣幼苗为材料,检测了分离自细果角茴香的生物碱对莴苣幼苗根生长及根毛发育的影响。结果表明:50~200μmol·L-1浓度范围内,8-甲氧基二氢血根碱对莴苣幼苗根长显著抑制;10、20和30μmol·L-18-甲氧基二氢血根碱对莴苣幼苗根毛的长度和数量有显著的抑制作用,且抑制作用均表现了浓度依赖性。通过对莴苣根尖细胞有丝分裂研究发现,50μmol·L-1的8-甲氧基二氢血根碱能显著抑制根尖细胞的有丝分裂,而且莴苣幼苗净增值率与根尖细胞的有丝分裂之间呈正相关,证明8-甲氧基二氢血根碱主要通过抑制根尖细胞有丝分裂对莴苣根的生长产生影响。     

白杨派杂种无性系生根特性研究

通过对采用杂交育种方法选育出的白杨无性系生根性状进行研究。结果表明,新无性系在最早生根时间、主侧根总数量、主侧根总长度等指标上均存在极显著差异,说明各无性系的生根能力具有显著差异。主根平均根数和侧根平均根数两个性状的遗传方差均大于环境方差,其重复力分别可达95％和87％。进一步分析结果表明易生根的无性系根原基数量最多,平均每段插穗约14．7～7．3个．而较难生根的无性系平均每段插穗约5．5～6．8个,难生根的毛白杨根原基数量最少,平均每段插穗约3．3个。通过层次分析法(AHP)对各无性系生根特性的综合评价结果表明：9606、9603、9608、9607、9614、9610、9602等7个无性系生根能力均优于其亲本和毛白杨。     

根瘤形成过程中豆科植物根毛和根外层传递细胞的诱发

对7种豆科植物接种根瘤菌后根部的形态和内部结构进行了研究.结果表明:根瘤菌可诱发根瘤形成部位根段的根毛增生、形变和根外层传递细胞的发育.根外层传递细胞发生在根毛伸长形变时期,一直可持续到根瘤形成,传递细胞壁内突发育过程是先由根表皮细胞外切向壁一侧细胞质膜向细胞质内陷形成囊状壁傍体,次生细胞壁物质在初生壁上沉积并逐渐充满囊状体,最终形成传递细胞典型的壁内突结构.根瘤形成过程中根外层传递细胞的诱发与培养方式(水培、固培)没有直接关系.在不接菌的对照苗的根段内未发现壁内突结构,研究证明豆科植物根外层传递细胞的形成是由根瘤菌诱导所致.     

Root Strength and Root Area Ratio of Forest Species in Lombardy (Northern Italy)

Forest vegetation is known to increase hillslope stability by reinforcing soil shear resistance and by influencing hydrologic conditions of soil. Although the importance of plant root systems for hillslope stability has received considerable attention in recent years, the quantification of such an effect needs more investigation. In this paper, we present a synthesis of the data gathered in the last 5 years for some species in different locations of the Alps and Prealps of Lombardy (Northern Italy) with the aim to increase our knowledge on root tensile strength and on Root Area Ratio distribution within the soil. Concerning root tensile strength we developed tensile strength–diameter relationships for eight species: green alder (Alnus viridis(Chaix) D.C.), beech (Fagus sylvatica L.), red willow (Salix purpurea L.), goat willow (Salix caprea L.), hazel (Corylus avellana L.), European ash (Fraxinus excelsior L.), Norway spruce (Picea abies (L.) Karst.) and European larch (Larix decidua Mill.). Results show a great variability among the different species and also for the same species. In general, however, root strength (in terms of tension) tends to decrease with diameter according to a power law, as observed by other Authors. Comparing the power law fitting curves for the considered species, it can be observed that they fall in a relatively narrow band, with the exception of hazel, which appears the most resistant. Concerning the evaluation of root distribution within the soil we estimated the Root Area Ratio (the ratio between the area occupied by roots in a unit area of soil) according to its depth for five species (beech, Norway spruce, European larch, mixed hazel and ash) in three locations of Lombardy. Results show that there is a great variability of root density for the same species well as for different points at the same locality. The general behaviour of root density, in any case, is to decrease with depth according to a gamma function for all the studied species. The results presented in this paper contribute to expanding the knowledge on root resistance behaviour and on root density distribution within the soil. The studied location have allowed the implementation of soil–root reinforcement models and the evaluation of the vegetation contribution to soil stability.     

Root decisions

Root systems have recognizable developmental plans when grown in solution or agar; however, these plans often must be modified to cope with the prevailing conditions in the soil environment such as the avoidance of obstacles and the exploitation of nutrient-rich patches or water zones. The modular structure of roots enables them to respond to their environment, and roots are very adaptive at modifying growth throughout the root system to concentrate their efforts in the areas that are the most profitable. Roots also form associations with microorganisms as a strategy to enhance resource capture. However, while the responses of roots in nutrient patches are well-recognized, overall 'rules of response' and variation in strategy among plant species that can be applied in a number of different environments are still lacking. Finally, there is increasing evidence that root–root interactions are much more sophisticated than previously thought, and the evidence for roots to identify self from non-self roots will be briefly discussed.     

The Root Cap Cuticle: A Cell Wall Structure for Seedling Establishment and Lateral Root Formation

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Phosphate Availability Alters Lateral Root Anatomy and Root Architecture of Fraxinus mandshurica Rupr. Seedlings

Plants have evolved some mechanisms to maximize the efficiency of phosphorus acquisition. Changes in root architecture are one such mechanism. When Fraxinus mandshurica Rupr. seedlings were grown under conditions of low phosphorus availability, the length of cells in the meristem zone of the lateral roots was longer, but the length of cells in the elongation and mature zones of the lateral roots was shorter,compared with seedlings grown under conditions of high phosphorus availability. The elongation rates of primary roots increased as phosphorus availability increased, but the elongation rates of the branched zones of the primary roots decreased. The number of lateral root primordia and the length of the lateral roots decreased as phosphorus availability increased. The topological index (altitude slope) decreased as phosphorus availability increased, suggesting that root architecture tended to be herringbone-like when seedlings were grown under conditions of low phosphate availability. Herringbone-like root systems exploit nutrients more efficiently, but they have higher construction costs than root systems with a branching pattem.     

Phosphate Availability Alters Lateral Root Anatomy and Root Architecture of Fraxinus mandshurica Rupr. Seedlings

Plants have evolved some mechanisms to maximize the efficiency of phosphorus acquisition.Changes in root architecture are one such mechanism. When Fraxinus mandshurica Rupr. seedlings were grown under conditions of low phosphorus availability, the length of cells in the meristem zone of the lateral roots was longer, but the length of cells in the elongation and mature zones of the lateral roots was shorter,compared with seedlings grown under conditions of high phosphorus availability. The elongation rates of primary roots increased as phosphorus availability increased, but the elongation rates of the branched zones of the primary roots decreased. The number of lateral root primordia and the length of the lateral roots decreased as phosphorus availability increased. The topological index (altitude slope) decreased as phosphorus availability increased, suggesting that root architecture tended to be herringbone-like when seedlings were grown under conditions of low phosphate availability. Herringbone-like root systems exploit nutrients more efficiently, but they have higher construction costs than root systems with a branching pattern.     

The Developmental Anatomy of the Seminal Root of Wheat

Wheat embryo usually gives rise to five seminal roots in matured caryopsls, although, the sixth root might develop in some cases. The first one is known as the primary root. Primary root emerged early, and its primodium was distinctly originated from the proembryo and could be gradually identified as three layers of initials. Lateral seminal roots emerged later from the embryonic axis in pairs, and originated from the surrouding cells of the procambium. Differentiation of lateral roots was much more vigorous than that of the first seminal root (primary root), and, its mother cells of metaxylem vessel appeared soon, Lateral seminal roots usually had more metaxylem vessels. In short, only the first root is the primary root, the lateral seminal roots are adventitious in nature, since their structures are similar to those of other adventitious roots.     

3种荒漠盐生植物根系及根毛形态特征的比较研究

在水培条件下,针对梭梭、囊果碱蓬和钠猪毛菜3种荒漠盐生植物,研究它们苗期在不同盐浓度条件下根系和根毛形态的差异。结果表明：一定浓度的盐分可以促进3种盐生植物生长,但较高浓度的盐抑制其生长,特别是对根系生长的抑制作用更大。在同样盐浓度下,钠猪毛菜的生长最快,生物量也最大。在盐分浓度较低时,3种盐生植物的主根长和总根长都有所增加,与对照相比,囊果碱蓬增加的幅度较大,但高浓度的盐会抑制根系总长度的增加,其中囊果碱蓬较梭梭和钠猪毛菜抑制的程度轻。盐分对3种植物的根系平均直径没有显著的影响,但有减小的趋势。在水培条件下,梭梭和囊果碱蓬的根系上、中、下部分布的较均匀,而钠猪毛菜的根系中部比上部和下部有显著的增加,盐分对每种植物的根系的分布没有显著的影响。3种植物的根毛与根系生长环境中的盐浓度没有明显相关性;3种植物之间,根毛的长度和密度有显著差异。从根系和根毛的形态特征可以推断：囊果碱蓬比梭梭和钠猪毛菜具有较强的抗旱性和耐极薄能力;梭梭的耐盐能力较其它2种植物差,囊果碱蓬的耐盐性最强。     

Influences of Root Diameter, Tree Age, Soil Depth and Season on Fine Root Survivorship in Prunus avium

The rapid turnover of the fine root system is a major pathway of carbon and nutrient flow from plant to soil in forest ecosystems. In order to quantify these fluxes there is a need to understand how fine root demography is influenced by edaphic, environmental and plant ontogenetic factors. We studied the influence of four major factors (season, depth, root diameter and tree age) on the survivorship and longevity of fine roots of Prunus avium L. (wild cherry) over two years in North East Scotland. Survival analysis of data derived from minirhizotron observations showed that, for the range of root diameters studied, an increase in root diameter of 0.1 mm was associated with a 16% decrease in the risk of death. Depth was also an important factor; roots present at a depth of 10 cm had significantly lower survivorship than did roots at all lower depths studied. The effects of tree age and season on root production were more complex. Roots of old trees were more likely to die in the spring and roots of young trees were more likely to die in the autumn. Our data illustrate the complex factors that must be taken into account when scaling up information from individual observations of root longevity to model the contribution of fine roots to C and nutrient fluxes in forest ecosystems.