Influence of storage methods on corn root length measurements

This study evaluated the changes in root length, mass, and diameter after air drying and rehydration of corn (Zea mays L.) root samples. For corn roots washed from soil, rehydrated root length was not reduced when compared with fresh root length, but rehydrated root mass was reduced to about half of fresh root mass, and rehydrated root diameter was approximately 75% of fresh diameter. Three storage methods (air dried, 70% ethanol, and 5% formaldehyde solution) were also compared for corn roots grown in moist paper towels. Although root mass and diameter were significantly reduced by air drying, root length was not altered by any of the treatments.     

梯田埂坎立地植物根系分布特征及其对土壤水分的影响

在标准株选择的基础上,采用整株挖掘法研究活性根的特征,采用旱季0～200cm土层土壤水分定点观测的方法观测土壤含水量,并籍此计算土壤水分相对亏缺值来描述梯田埂坎附近土壤水分的变化。研究显示,4个植物种在根系深度、生物量和根长分布、对土壤水分的影响方面具有不同的特征。柽柳根系深达757cm,根系生物量和根长在0～100cm土层范围内均匀减少。但粗根在整个根系中占支配地位,细根的生物量和根长主要集中在0～40cm土层中。杞柳根系分布在0～40cm土层中,占全部根系生物量的86．0％。但粗根占绝对优势。40cm以下土层中(杞柳根系分布的最大深度为305cm)根系生物量和根长逐渐下降,但细根长度超过粗根。杞柳的部分根系分布高于着生平面,而且这部分根系中细根占绝对优势。柠条的根系分布特征与杞柳相似,但粗根的比例大于杞柳。新疆杨根系分布较浅,最大深度仅为136cm。在0～40cm土层中,新疆杨根系生物量占总根系生物量的77．2％。60cm土层以下根系生物量急剧下降,根长在80cm以下同样急剧减少。在新疆杨的整个根系分布层中,虽然粗根在生物量上占优势,但细根长度远大于粗根。研究结果还显示,栽植不同植物种的埂坎附近水平范围内存在明显的土壤水分亏缺。柽柳埂坎、杞柳埂坎、拧条埂坎、新疆杨埂坎的水分亏缺范围分别为230cm,437cm,274cm和399cm。垂直范围内,在4个测点均有一个土壤水分从表层往下增加的土层,该层在30～70cm范围内变化,只是随距埂坎的距离和植物种不同而不同。增加层以下,土壤水分开始持续下降至70cm到200cm土层,具体的下降深度也因植物种和距埂坎的距离不同而不同。建议,(1)根系深、对土壤水分影响较小的柽柳是黄土高原地区较为理想的农林复合树种;(2)杞柳应栽植在梯田软硬埂的结合部,约在梯田埂坎高度的1／3到2／3处,并且采取及时平茬和秋粮作物配置的方法调控系统的竞争关系;(3)柠条可采取与杞柳相似的栽植和调控办法;(4)根系分布浅、对水分影响较大的新疆杨,除栽植在埂坎顶部外成活比较困难,不是合适的埂坎栽植树种。     

Influence of Fusarium solani on citrus root rot caused by Phytophthora parasitica and Phytophthora citrophthora

Interactions between Fusarium solani and Phytophthora parasitica or F. solani and P. citrophthora influenced the development of root rot of citrus but depended on the temporal order of inoculation with F. solani or the two Phytophthora spp. Inoculation of citrus with either Fusarium solani and Phytophthora parasitica or Phytophthora citrophthora increased root rot compared to inoculation with P. parasitica or P. citrophthora alone when plants were inoculated with Phytophthora by dipping their roots in zoospore suspensions and subsequently transplanted into soil infested with F. solani. However, root rot was not increased by simultaneous co-inoculation of P. parasitica and F. solani or when plants were inoculated with F. solani first. Root rot was not increased when heat-stressed or non-stressed plants were inoculated with P. parasitica 30 days after transplanting into soil infested with F. solani. In most but not all experiments, F. solani alone reduced growth of tops or roots a small but significant amount.Co-inoculation of citrus by root-dipping into zoospore suspensions of P. parasitica and transplanting into soil infested with F. solani reduced feeder root length by 62% and root weight by 61% but did not significantly reduce the percentage of living roots when compared to inoculation with P. parasitica alone. When citrus roots were immersed in zoospore suspensions of P. citrophthora and transplanted into soil infested with F. solani, feeder root length was reduced by 68%, but feeder root weight and the percentage of living roots were not significantly reduced when compared to plants inoculated with P. citrophthora alone.Propagule densities of both P. parasitica and P. citrophthora in the rhizosphere of plants inoculated by root-immersion and then transplanting into soil infested with F. solani were not significantly different than propagule densities from plants transplanted into non-infested soil. Propagule densities of P. parasitica were suppressed an average of 41% when citrus was inoculated with P. parasitica 30 days after transplanting into soil infested with F. solani and by 41% when citrus was co-inoculated by transplanting into soil infested with both F. solani and P. parasitica.     

Development and validation of a model to describe root length density of maize from root counts on soil profiles

Root length density (RLD) is an important determinant of crop water and nutrient acquisition, but is difficult to measure in the field. On a soil profile, in-situ counts of root impacts per unit surface on soil profiles (NI) can be used to calculate RLD if crop-specific parameters for preferential root orientation (anisotropy) are known. An improved method for field determinations of RLD was developed and validated for maize at sites in Côte d'Ivoire and Burkina Faso. Root anisotropy was measured with cubes of undisturbed soil with 0.1 m sidelength, based on NI observed on three planes oriented perpendicularly to each other. RLD was also measured for the enclosed volume. Repetition of such measurements enabled estimation of the robustness across sites of empirical and geometric models for the relationship between RLD and NI:RLD = NI CO, with CO being the coefficient of root orientation, theoretically equals 2 for an isotropic distribution. Root systems were found to be nearly isotropic, except near the root front (0.3 to 0.5 m), where roots had a preferentially orthotropic orientation. Measured RLD was generally about 50% larger than RLD calculated from observed NI and CO, indicating that at least one of the measurement techniques had a systematic error. The ratio between measured and calculated RLD (CE), which ranged from 0.8 to 2, increased with the age of the plants and decreased with soil depth. CE was therefore introduced as an additional coefficient, resulting in RLD = NI CO CE. The empirical value for CO CE was between 2 and 5. The empirical coefficients CO and CE were the same for the sites in Cote d'Ivoire (oxisol with an iron pan at 0.6 to 0.9 m) and Burkina Faso (alfisol with an iron pan at 0.4 to 0.8 m). The model was validated with independent data sets at both sites, and gave satisfactory predictions of RLD on the basis of NI obtained from single soil planes, which can be easily measured in the field.     

Earthworm effect on root morphology in a split root system

Plants respond to their environment through adaptations such as root proliferation in nutrient-rich patches. Through their burrows and casts production in soil, earthworms create heterogeneity which could lead to local root adaptations or systemic effects. To investigate the effect of earthworms on root system morphology and determine whether earthworm effect is local or systemic, we set up two independent split root experiments with rice or barley, (i) without earthworm (CC), (ii) with earthworms in both compartments (EE), and (iii) with earthworms in one single compartment (CE). Earthworms had an effect on belowground plant biomass. The relative length of thick roots decreased with an increasing abundance of earthworms. Some root diameter classes responded to earthworm number in a linear or curvilinear way, making simple conclusions difficult. We found no difference in root biomass or morphology between the two compartments of the split root system in the CE treatment, but a positive effect of earthworm biomass on root biomass, volume, surface area, and length at the whole plant level. Results supported a systemic effect dependent on earthworm abundance. Modification of nutrient mineralization, soil physical structure, and/or the concentration of signal molecules could all be responsible for this systemic effect.     

The effect of abscisic acid on root and shoot growth of cauliflower plants

Addition of abscisic acid (ABA) to the nutrient solution increased the root to shoot ratio of hydroponically-grown cauliflower plants by reducing the dry weight of the shoot and increasing that of the root. At concentrations higher than 10^–7 M, ABA increased root branching and root hair formation. Root extension was inhibited in plants kept continuously in solutions containing high ABA concentrations but following removal from the ABA solution root elongation was increased in comparison with plants given no ABA treatment. This elongation was greatest in plants with increased root branching caused by higher ABA concentrations.     

Soil redox-pH stability of arsenic species and its influence on arsenic uptake by rice

Although the auger method has been reported to be simple and superior to other methods of determination of roots, a standard procedure of determining roots with the same is lacking. In a bid to standardize the auger method for studying wheat root distribution; we sampled roots with 5, 7.5 and 10 cm ID augers on the row and midway between rows down to 180 cm. The suitability of a sampling scheme was adjudged from bias between observed and actual root length densities (RLD). The actual density in a layer was obtained by integrating the equation fitted to the average of root density data horizontally between 0 and 11 cm, because for 22 cm apart rows of wheat the representative half of the unit soil strip was 11 cm from the row; and assumed actual RLD was the average of horizontal distribution of RLD in a particular layer. Single site sampling on the row or between rows gave the maximum bias. Average of two sites viz. on the row and midway between rows with 10 cm ID auger and 7.5 cm ID auger or at three sites with 5 cm ID auger (additional site midway between the earlier two) gave the best estimates in that order.     

Plant functional traits and soil microbial biomass in different vegetation zones on the Loess Plateau

Plant functional traits built the relationships between plant diversity, species composition, and physiology along with the environmental changes, thus influencing soil microbial community. As the sensitivity indicators, soil microbial biomass and plant functional traits responses soil micro-organism and plant characteristics in direct way. Ten plant functional traits of 149 species and soil microbial biomass (carbon, nitrogen, and phosphorus) were analyzed across the different vegetation types (forest, forest-steppe, and steppe) that are divided by environmental gradient (temperature and precipitation), aimed to find the correlations among them. Our results confirmed the greatest values of plant functional traits (except the leaf density and the fine root density) that were distributed in the steppe zone, mainly due to the different mean annual temperature and mean annual precipitation conditions. For different plant growth forms, the plant functional traits were significant differences among the vegetation zones. The advantages of higher rate nutrient cycling, plentiful biomass supplements, and favorite habit conditions lead to the forest-steppe zone with the highest C_mic and N_mic concentrations. The canonical correlation analysis indicated that leaf nitrogen, root nitrogen, and fine root densities were correlated with root exudate and tissue which affected the concentrations of soil organic carbon (SOC) and total nitrogen (N), consequently impacting soil microbial biomass carbon (C_mic) and soil microbial biomass nitrogen (N_mic). Soil is the medium that connects micro-organism and plant root system that influenced leaf nitrogen, root nitrogen, and fine root density of plant functional traits, the concentrations of SOC and total N that plant feedback are consequently influencing C_mic and N_mic.     

超绿水稻品种（系）‘沈农19-6’根系的生长和生理特性初探

采用盆栽方法,研究不同生育时期超绿水稻品种（系）‘沈农19-6’根系的生长和生理特性。结果表明,生育后期品种（系）‘沈农19-6’的最大根长、根体积、根干重和根冠比显著或极显著大于‘沈农07-015’和‘丰锦’;根系氧化能力（α-萘胺氧化量）和根系还原能力均高于‘沈农07-015’和‘丰锦’。上述指标在整个生育期内的变化趋势与‘沈农07-015’和‘丰锦’基本上一致,但在生育后期其根系衰老速度缓慢,根系活力高。     

树木根系碳分配格局及其影响因子

根系作为树木提供养分和水分的“源”和消耗C的“汇”,在陆地生态系统C平衡研究中具有重要的理论意义。尽管20多年来的研究已经认识到根系消耗净初级生产力占总净初级生产力较大的比例,但是,根系（尤其是细根）消耗C的机理以及C分配的去向一直没有研究清楚。主要原因是细根消耗光合产物的生理生态过程相当复杂,准确估计各个组分消耗的C具有很大的不确定性,常常受树种和环境空间和时间异质性、以及研究方法的限制。综述了分配到地下的C主要去向,即细根生产和周转、呼吸及养分吸收与同化、分泌有机物、土壤植食动物,及有关林木地下碳分配机理的几种假说,分析了地下碳分配估计中存在的不确定性。目的是在全球变化C循环研究中对生态系统地下部分根系消耗的C以及分配格局引起重视。     

Effects of Soil Structure on Pea (Pisum sativum L.) Root Development According to Sowing Date and Cultivar

Spring peas are known to be very sensitive to compaction, particularly when sowing takes place soon after winter. Winter peas, which are sown in autumn, should present an opportunity to sow the crop in better soil structural conditions than for spring peas, because of more favourable moisture conditions at that time. As environmental conditions have a big influence on root systems, it is important to determine the effects of soil structure on pea root systems for different cultivars and sowing dates. A spring pea cultivar and a winter pea cultivar were both sown at two dates (one in autumn and one in spring) on soils with different plough-layer structures (compacted and uncompacted) at two sites in 2002 and one site in 2003. Soil structure was characterised by bulk density and the percentage of highly compacted zones in the ploughed layer. Root distribution maps were produced every month, from February to maturity. Root development was described in terms of general root dynamics, root elongation rate (RER) in the subsoil, final maximum root depth (Dmax) and root distribution at maturity. Root depth dynamics depended on compaction and its interaction with climatic conditions. The effects of compaction on RER in the subsoil depended on the experimental conditions. Dmax was reduced by 0.10 m by compaction. Compaction also reduced root distribution between 10 and 40% in the ploughed layer only. Pea cultivars differed in sensitivity to soil compaction, with a direct effect on the final depth explored by roots. These results are discussed in terms of their relevance to water and nutrient uptake.     

Genotype and Planting Density Effects on Rooting Traits and Yield in Cotton （Gossypium hirsutum L,）

Root density distribution of plants is a major Indicator of competition between plants and determines resource capture from the solh This experiment was conducted in 2005 at Anyang, located in the Yellow River region, Henan Province, China. Three cotton （Gossyplum hlrsutum L.） cultivars were chosen： hybrid Btcultlvar CRI46, conventional Btcultlvars CRI44 and CRI45. Six planting densities were designed, ranging from 1.5 to 12.0 plants/m^2. Root parameters such as surface area, diameter and length were analyzed by using the DT-SCAN Image analysis method. The root length density （RLD）, root average diameter and root area Index （RAI）, root surface area per unit land area, were studied. The results showed that RLD and RAI differed between genotypes; hybrid CRI46 had significantly higher （P 〈0.05） RLD and RAI values than conventlonal cultlvars, especially under low planting densities, less than 3.0 plants/m^2. The root area index （RAI） of hybrid CRI46 was 61% higher than of CRI44 and CRI45 at the flowering stage. The RLD and RAI were also significantly different （P = 0.000） between planting densities. The depth distribution of RAI showed that at Increasing planting densities RAI was Increasingly distributed in the soil layers below 50 cm. The RAI of hybrid CRI46 was for all planting densities, obviously higher than other cultivars during the flowering and boll stages. It was concluded that the hybrid had a strong advantage in root maintenance preventing premature senescence of roots. The root diameter of hybrid CRI46 had a genetically higher root diameter at planting densities lower than 6.0 plants/m^2. Good associations were found between yield and RAI In different stages. The optimum planting density ranged from 4.50 plants/m^2 to 6.75 plants/m^2 for conventional cultlvars and around 4.0-5.0 plants/m^2 for hybrids.     

红砂根系分叉数和分支角度权衡关系的坡向差异

根系构型是决定根系分布及其对土体搜索效率的重要因素, 是植物与资源环境异质性相互适应的结果。利用ArcGIS建立研究区域的数字高程模型(digital elevation model), 采用全根系挖掘法, 研究了祁连山北坡荒漠草原不同坡向红砂(Reaumuria songarica)根系分叉数和分支角度的关系。结果表明: 不同坡向梯度草地群落的盖度、密度、高度和土壤含水量呈不同的变化趋势(p < 0.05), 红砂种群的密度、高度和根冠比等生物学特征的变化规律存在差异(p < 0.05); 不同坡向红砂根系分叉数和分支角度的相关性存在差异(p < 0.05), 在南坡和北坡红砂根系分叉数和分支角度之间存在极显著的负相关关系(p < 0.01), 在东坡和西坡根系分叉数和分支角度之间存在显著的负相关关系(p < 0.05), 红砂根系分配给根系分叉数和分支角度的资源存在着“此消彼长”的权衡关系; 随着坡向由南坡向西坡、东坡、北坡转变, 红砂根系分叉数和分支角度回归方程的标准化主轴斜率逐渐减小(p < 0.05), 红砂根系构型模式由扩散型转向聚集型。不同坡向红砂根系合理权衡连接长度和分支角度的资源配置模式, 反映了异质生境中植物种群应对资源多重竞争的环境生态适应机制。     

The influence of medium aeration on in vitro rooting of Australian plant microcuttings

Media with different air filled porosity were compared with standard agar medium for root induction and root elongation for two Australian plants Grevillea thelemanniana and Verticordia plumosa×Chamelaucium uncinatum. Microcuttings from shoot cultures were pulsed for 7 days on a high auxin (40 M IBA), agar-solidified medium in the dark. The rooting of the microcuttings was then compared on standard agar medium (M1, 1/2 MS, no hormones) and on three experimental treatments: – porous-agar medium (1/2 MS, no hormones, 30 g agar l^–1, solidified then blended to provide aeration); – white sand, or white sand wet with M1 medium; and – a sterile propagation mix. The protocol using the propagation mix is referred to as IVS (In Vitro Soil). A separate experiment involved flushing the IVS soil profile with low or normal oxygen. The controls on M1 medium showed low and variable rooting percentages. The rate of root induction and the average total root length per microcutting at final harvest was significantly higher using the IVS protocol, porous-agar or white sand, while addition of agar medium to sand suppressed the percentage rooting and elongation as did flushing the air space in the IVS rooting medium with low oxygen. Other species tested on M1 medium and IVS including Pimelea physodes, Conospermum eatoniae, Verticordia grandis, and a Chamelaucium megalopetalum×C. uncinatum hybrid all showed a significant improvement on the IVS system. The IVS culture technique reduces plant-handling costs.     

Influence of root density on the critical soil water potential

Estimation of root water uptake in crops is important for making many other agricultural predictions. This estimation often involves two assumptions: (1) that a critical soil water potential exists which is constant for a given combination of soil and crop and which does not depend on root length density, and (2) that the local root water uptake at given soil water potential is proportional to root length density. Recent results of both mathematical modeling and computer tomography show that these assumptions may not be valid when the soil water potential is averaged over a volume of soil containing roots. We tested these assumptions for plants with distinctly different root systems. Root water uptake rates and the critical soil water potential values were determined in several adjacent soil layers for horse bean (Vicia faba) and oat (Avena sativa) grown in lysimeters, and for field-grown cotton (Gossypium L.), maize (Zea mays) and alfalfa (Medicago sativa L.) crops. Root water uptake was calculated from the water balance of each layer in lysimeters. Water uptake rate was proportional to root length density at high soil water potentials, for both horse bean and oat plants, but root water uptake did not depend on root density for horse bean at potentials lower than −25 kPa. We observed a linear dependency of a critical soil water potential on the logarithm of root length density for all plants studied. Soil texture modified the critical water potential values, but not the linearity of the relationship. B E Clothier Section editor     

Consequences of root growth kinetics and vascular structure on the distribution of lateral roots

It has been proposed that the acropetal initiation of lateral roots is a built‐in process specified as part of the general process of cell division and differentiation in the parent root tip. Conversely, it is commonly reported that root branching is essentially a variable feature. In the present study, the interlateral distance along the parent root has been investigated using three banana varieties (Musa spp.) grown in two substrates. The pattern of lateral root initiation was obscured by variations of root growth patterns and vascular structure among roots, genotypes and substrates. A framework model is formulated showing the influence of growth pattern and vascular structure on branching density. The model raises a distinction between growth components which should not affect the branching density (i.e. rate of cell division) and which may affect it (i.e. size of mature cells and number of transverse divisions performed by cells executing their trajectory in the meristem). It appears also that lateral root density and root growth rate might be independently modulated by appropriate changes of root growth patterns, in banana and presumably many other taxa.     

Trade-off relationship between root forks and branch angle of Reaumuria songarica on different aspects of slopes

Aims Root architecture is a major determinant in root spatial distribution and soil searching efficiency, may reflect plant strategies to adapt to the environments. Our objective was to examine the relationship between root forks and branch angle of Reaumuria songarica in response to slope aspects in the northwest of China.Methods The study site was located in desert grasslands on the northern slope of Qilian Mountains, Gansu Province, China. Survey and sampling were carried out along 20 belt transects. It were set up on sites of four different slope aspects at intervals of 30 m vertically from elevation 1940 m of the study area moving upward, 6 plots were set up flatly on site of each belt transect at intervals of 20 m. A handheld GPS was used to record longitude, latitude and altitude of each plot. ArcGIS was used to set up digital elevation model to extract the information of elevation, aspect, and slope for each plot. The traits of plant communities were investigated and 1 individual’s samplings of R. songarica were used to measure the root forks, root length and root branch angle in laboratory in each plot, and biomass of different organs was measured after being dried at 80 °C in an oven. The 120 plots were categorized into groups of south, west, east, and north aspects of slopes, and the linear regression analysis was then used to examine the trade-off relationship between root forks and branch angle in various groups.Important findings The results showed that with the slope aspect turned from south, west, east to north, the density, cover, height, above biomass and soil moisture content of the plant community displayed a pattern of initial increase, while the height, root-shoot ratio, root branch angle of R. songarica displayed a pattern of initial decrease, and the density, specific root length, root forks increase. The number of root forks was negatively associated with the branch angle, but the relationship varied along the aspect gradient (p < 0.05). There was a highly significant negative correlation (p < 0.01) between the root forks and branch angle on north slope and south slope, whereas less significant (p < 0.05) on the east slope and west slope. There is a trade-off relationship between the root forks and link length. In addition, when the slope aspect changed from south to west, east and north, the standardized major axis slope of regression equation in the scaling relationships between root forks and branch angle decrease (p < 0.05), indicating that the root architecture model of R. songarica by diffusion to gather. Consequently, the patterns of resource allocation between root forks and branch angle in different slope habitats reflected the mechanism of environment adaptation under conditions of multiple competitions for resources in plant populations.     

氮有效性增加对细根解剖、形态特征和菌根侵染的影响

氮(N)有效性增加对森林生态系统结构和功能有重要影响.细根作为树木地下最为活跃的组分,其对N有效性增加的响应已成为森林生态学研究的热点.本文对N有效性增加条件下细根解剖构造、形态和菌根侵染的响应趋势及潜在机制进行了综述.N有效性增加导致细根皮层厚度、皮层层数和皮层细胞直径下降,外皮层上通道细胞数量减少,而中柱和木质部横截面积,以及导管(或管胞)直径、数量和壁厚度均增加,根解剖构造的响应与植物激素浓度变化有关;N有效性增加后菌根侵染率下降,比根长(单位根干质量的长度)在外生菌根树种中普遍下降,而在内生菌根树种中增加;根直径和组织密度的变化趋势则表现出较大的种间差异.这些个体根和树种水平上的结果对于理解森林生态系统水平上的碳和养分循环具有重要意义.最后,根据目前研究中存在的不足提出了今后的研究方向与问题.