山新杨高效组培再生体系的建立

以山新杨(P.davidiana×P.bolleana)叶片为外植体,1/2MS为基本培养基,对适合山新杨叶片再生的生长调节剂6-BA和NAA进行研究。结果表明:适宜山新杨叶片分化培养基是1/2MS+NAA 0.05 mg/L+6-BA 0.5 mg/L;继代抽茎培养基是1/2MS+NAA 0.08 mg/L+6-BA 0.1 mg/L;最佳生根培养基是1/2MS+IBA 0.3 mg/L。     

铝胁迫对海南花生根系的研究初报

采用水培方法，研究不同Al³⁺浓度处理对海南省本地农家种花生的根系生长、性状指标和生物量的影响。结果表明：(1)50 μmol/L Al³⁺处理下的本地种花生的根长显著短于0 μmol/L Al³⁺处理下的根长，100 μmol/L Al³⁺处理下本地种花生根系生长发育受到严重抑制。(2)100 μmol/L Al³⁺处理下，本地种花生株高和基茎直径显著小于0 μmol/L Al^{3+相似文献}   

腾冲过路黄的生长动态观察研究

对腾冲过路黄的物候期进行观察，并绘制出物候图谱。测定其各器官生长动态，结果显示：腾冲过路黄的根系集中分布层深度为10～26 cm，其茎含水量平均为82.02％，叶含水量平均为79.87％，根含水量平均为85.68％。采用相关分析及建立生物量一元线性回归方程，茎、叶、根的生物量（干重Y）可分别用Y=0.0213X4.3369、Y=0.0565X3.9657、Y=0.0382X3.517来推测。     

FLOODING STRESS: The Effects of Planting Pattern and Water Regime on Root Morphology,Physiology and Grain Yield of Rice

Field experiments were conducted over two growing seasons to investigate the effects of variations in water regime and planting pattern on the growth of rice plant roots and shoots and on yield. Four water regimes were evaluated with split plot design: intermittent flooding during the vegetative stage only (IF‐V); intermittent flooding extending into the reproductive stage (IF‐R); not flooded (NF); and continuously flooded (CF), interacting with three different planting patterns: single seedling per hill with wider 30 × 30 cm spacing (P1); single seedling per hill with closer 20 × 20 cm spacing (P2); and three to four seedlings per hill with 20 × 20 cm spacing (P3). The treatment combination CF/P3 corresponds most closely with current conventional practice. The other combinations were evaluated to contribute to a better understanding of the effects of the two parameters studied, respectively and together. IF‐V/P1 was considered as an approximation of System of Rice Intensification (SRI) practice. This study found that the combination of singly transplanted seedlings, both P1 and P2, with the IF‐V water regime improved root length density, root physiological activity, and chlorophyll content of the upper and lower leaves, leading to higher grain yield compared with the other treatment combinations. With continuous flooding (CF), P2 gave 23 % more yield compared with the P3 planting pattern. Combining IF‐V and P2 produced 32 % more grain yield compared with the CF/P3 treatment. These results showed a synergistic effect on grain yield from reduced intra‐hill competition and IF‐V water management. In these trials, there was no significant yield difference between the IF‐V/P1 and CF/P3 treatments. Wider spacing improved the performance of individual hills when grown under IF‐V water regimes, but tiller number per unit area remained a dominant determinant of yield. The yield reduction observed for CF/P1 compared with CF/P3 indicated that in more hypoxic CF soils, denser plant populations can produce more than sparser ones, whereas the latter benefit from more aerobic soil conditions. Intermittent irrigation during the vegetative growth stage and transplanting single seedlings/hill are major elements of SRI methodology. These findings contribute to an understanding of why SRI methods can produce the higher yields reported. A consideration of the effects of interaction between planting pattern and water regime shows the need to establish empirically the optimum values for these treatments according to varietal, soil and climatic characteristics for the greatest yield response.     

Contributing traits for nitrogen use efficiency in selected wheat genotypes and corollary between screening methodologies

ABSTRACT

Nitrogen uptake being part of nitrogen use efficiency (NUE) is largely decided by root traits. Root traits variability has hardly been explored by breeders mainly because of difficulties in scoring. The hydroponic system requiring lesser space for precise phenotyping of large numbers of genotypes independently of the growing season can be a suitable alternative. However, the effectiveness of hydroponic screening methods needs to be verified under the soil condition of the field or pot. In the present study, root traits and NUE were investigated in 19 genotypes under two conditions (hydroponic and pipe filled with soil). Both environments revealed large variability for root traits and NUE under high and low N conditions establishing the absence of any direct selection for these traits in the past. Under both sets of experimentation, NUpE was largely responsible for improved nitrogen efficiency mainly because of higher root biomass. The significant association between the two screening methods i.e. hydroponic and pot filled with soil under both low and high N condition support large scale screening for root traits under hydroponic condition.     

Rhizosphere calcareous soil P-extraction at the expense of organic carbon from root-exuded organic acids induced by phosphorus deficiency in several plant species

The amount of organic acids in root exudates rapidly increases under phosphorus (P) deficiency. Loss of carbon from root-exuded organic acids, which are derived from plant net photosynthetic products, is generally considered negligible. The present study aimed to study the characteristics of root-exuded organic acids, extraction of phosphorus (P extraction) in calcareous soil and the expression of organic carbon from root-exuded organic acids in two woody Moraceae plants (Broussonetia papyrifera L. Vent and Morus alba L.) and two herbaceous cruciferous plants (Orychophragmus violaceus L. Schulz and Brassica napus L.) under two P levels (P-normal and P-deficient). P extraction and the amount of root-exuded organic acids simultaneously and disproportionately increased in the four plant species tested under P deficiency. The maximum P-extracting capability of the four plant species was observed after 40 days of treatment. Additionally, the response of root-exuded organic acids induced by P deficiency was species-specific. B. papyrifera extracted more P in calcareous soil, and expended less organic acid for the same P-extraction than M. alba. Similarly, O. violaceus extracted more P in calcareous soil, and consumed less organic acid for the same level of P-extraction than B. napus. Root-exuded oxalic and malic acids accounted for most of the increment of P extraction in woody Moraceae plants, while root-exuded citric acid accounted for most of the increment in P extraction in herbaceous cruciferous plants. B. papyrifera and O. violaceus exhibited the strongest P-extracting capability at lower expense of organic carbon over the treatment duration in the four plant species. O. violaceus had the most rapid response of root-exuded organic acids to P deficiency, while B. napus had the slowest response. Thus, rapid response with low organic carbon cost and high efficiency of extraction on P in calcareous soil may underlie the strong adaptability of B. papyrifera and O. violaceus to a Karst environment.     

苗木切根技术研究进展

精准培育的理念已经渗入到森林培育的各个环节。切根作为干扰根系最为重要的技术,也受到越来越多地重视。切根可以划分为芽苗切根、苗期切根和起苗后切根等3种类型,把平截、扭根、侧方修根、盒式修根等称为苗期切根,是狭义切根范畴。结合苗木形态指标、生理指标和造林效果,综述每一类型的切根对苗木质量和造林效果的影响。以辐射松为代表的主根发达树种,通过芽苗切根、苗期的平截和扭根,抑制根系顶端优势,从而降低苗木高生长,促进侧根发育,形成发达、紧凑的根系,调整苗木地上和地下比例,最终提高苗木造林效果。以花旗松为代表的慢生常绿树种,侧根较为发达,切根效果不一。苗木平截和扭根后,内源激素、矿质营养、碳水化合物、水分等均会发生变化,这种变化如何影响苗木质量的机制尚不明确。     

Soil bulk density corrections for providing a better relationship with root growth in gravelly soil

Abstract

Bulk density of a Tifton (Plinthitic Paleudult; fine loamy, siliceous, thermic) soil containing 5.8 to 11.0% of the sample weight as pebbles was 0.06–0.12 g/cc lower when corrections were made for presence of pebbles or concretions. A method for determining the bulk density of the soil matrix between pebbles or concretions is outlined. After adjustment, the bulk density at which root penetration was inhibited in this soil closely approximated that for soils which do not contain concretions. The proposed procedure reflects more nearly how bulk density changes where plant roots are growing than previously published procedures do.     

Short Root Densities and Surface Phosphatase Activities of Ectomycorrhizal Morphotypes in a Slash Pine Plantation

Abstract

Mineralization is the dominant process controlling soil-solution P in the Spodosols of the southeastern United States. Pine trees growing in these soils are typically colonized by ectomycorrhizal (EM) fungi that are known to produce phosphatases. Little, however, is known of the dynamics of EM short roots or phosphatase activity in tree plantations. To address this question, short root densities, EM morphotypes, and associated surface acid phosphomonoesterase in a 12-year-old Pinus elliottii plantation in northern Florida were evaluated. The density of total (living and dead) short roots changed little from February through June, with a mean of 7.6 cm³ soil. The majority of the short roots, however, were inactive or dead with only 14 to 38% appearing viable upon visual inspection. The majority of the viable short roots were mycorrhizal. The most abundant morphotypes were formed by Cenococcum and Thelephora but these had low phosphatase activity. In contrast, less frequently observed morphotypes had substantially higher rates of enzyme production and these may play an important role in sustainable P nutrition of plantation trees.     

Root Exudates of Rice Cultivars Affect Rhizospheric Phosphorus Dynamics in Soils with Different Phosphorus Statuses

Exudation of organic acids by the roots of three rice cultivars grown in three soils of different phosphorus (P) statuses, and their impacts on the rhizospheric P dynamics and P uptake by the rice plants, were investigated. Quantum root exudates from all the rice cultivars were significantly greater at 21 days after transplantation than at panicle initiation or flowering stages. Malic acid was the most predominant organic acid present in the rice root exudates (10.3 to 89.5 μmol plant^?1 d^?1), followed by tartaric, citric, and acetic acids. Greater exudation of organic acids from rice grown in P-deficient soil by all the rice cultivars suggested response of rice plant to P stress. Results indicate that the release of organic acids in the root exudates of rice plants can extract P from strongly adsorbed soil P fraction, thereby increasing native soil P utilization efficiency and ensuring adequate P nutrition for the growing rice plants.