水分驱动下茵陈蒿(Artemisia capillaris Thunb.)地上生物量模型与异速生长特征

构建生物量预估模型,探究生物量在各器官中的分配策略和异速生长关系及其对环境因子的响应,对理解植物群落结构、功能、碳储存和分配机制具有重要意义。本研究以内蒙古荒漠草原常见种茵陈蒿(Artemisia capillaris Thunb.)为对象,在不同水分处理下,利用易测指标,如株高、基径、分枝数、冠幅和生物量等参数建立生物量模型,采用标准化主轴分析法分析其异速生长关系。结果表明:在不同水分处理下,茵陈蒿的最佳生物量预估模型的变量选择不同;不同水分处理下茵陈蒿各器官间、各器官与地上生物量间的异速生长关系不同,但相对于自然降水量,增水和减水50%下均为等速生长,这说明在不同水分条件下茵陈蒿对各器官间的资源配置存在权衡策略,符合最优分配假说;而在极端气候条件下,各器官对资源的竞争会变弱;在荒漠草原中,对草本植物进行生物量模拟,选择预测变量和方程模型时,应考虑生长季降水量。本研究可为荒漠草原草本植物生物量预估模型的建立和异速生长关系对环境因子适应的理解等提供方法支持及理论依据。     

植物生长物质对大花红景天愈伤组织诱导及苗再生的影响

以大花红景天植物的茎、叶、芽、种子为材料,采用DPS软件正交设计法,通过添加不同植物生长物质,考察其对大花红景天愈伤组织形成及苗再生的影响,为低海拔条件下建立大花红景天植株再生体系提供数据基础。结果表明：种子和芽是诱导愈伤组织最适宜的外植体;植物生长物质对愈伤组织形成的影响大小为6-BA〉KT〉2,4-D〉NAA〉IAA,愈伤组织形成的最佳培养基为MS＋6-BA 4.0 mg.L-1＋KT 0.1 mg.L-1＋NAA 0.1 mg.L-1＋IAA 0.2 mg.L-1;不定芽分化的最佳培养基为MS＋TDZ 0.5 mg.L-1＋NAA 0.5 mg.L-1,诱导率达63.14%,不定芽数平均为11.4。本试验获得的最佳培养基配方,适宜在低海拔条件下进行快速诱导大花红景天的愈伤组织和植株再生。     

Efficient plant regeneration from protoplasts of Arachis paraguariensis Chod. et Hassl. using a nurse culture method

Factors influencing in vitro growth rates of soybean embryos were investigated using embryos isolated in the cotyledon stage. The influence of these factors on final plant recovery from the embryos cultured was tested. Sucrose and glucose could serve as carbon sources with final plant yields being higher with sucrose than with glucose. A culture medium containing only KNO₃ (25 mM) as the nitrogen source supported embryo growth. Adding glutamine (10 mM) to the medium containing KNO₃ increased final plant recovery to 25%. Of several vitamin supplements tested a combination of pyridoxine-HCl, nicotinic acid and pantothenic acid (0.5; 1.0; 0.5 mg l^-1) provided the best growth and plant yield. Of the plant growth regulators tested IAA, BAP and GA₃ stimulated embryo growth and plant development when added to the medium at a low concentration (0.1 M). The optimal temperature for in vitro growth of cotyledon stage embryos was 27°C. Temperatures above 30°C caused growth retardation and reduced plant yield. A protocol for culturing soybean cotyledon stage embryos under conditions ensuring high plant recovery is proposed.Abbreviations IBA indole-3-butyric acid - GA₃ gibberellic acid - IAA indole-3-acetic acid - NAA -naphthaleneacetic acid - BAP 6-benzylaminopurine - 2,4-D 2,4-dichlorophenoxyacetic acid     

污染土壤生物恢复技术

污染土壤生物恢复技术张春桂许华夏姜晴楠（中国科学院沈阳应用生态研究所,１１００１５）ＢｉｏｒｅｍｅｄｉａｔｉｏｎｏｆＣｏｎｔａｍｉｎａｔｅｄＳｏｉｌ．ＺｈａｎｇＣｈｕｎｇｕｉ,ＸｕＨｕａｘｉａ,ＪｉａｎｇＱｉｎｇｎａｎ（ＩｎｓｔｉｔｕｔｅｏｆＡｐｐ...     

Relationship of Apical Dominance to the Nutrient Accumulation Pattern in Pisum sativum var. Alaska

Decapitation of the pea plant resulted in the growth of all the lateral shoots. The initial growth of all lateral buds was somewhat similar. The differential growth rates developed later on. The pattern of growth of lateral shoots varied with the age of the plant when decapitation was performed. The basal shoots dominated when the plants were decapitated at the 2-leaf stage. At 3-leaf stage decapitation resulted in the dominance of shoot 5. Decapitation at 4-or-more-leaf stage resulted in the eventual dominance of the suhterminal lateral shoot. As a rule P-32 moved to the most actively growing part of the plant, i.e. apex in intact vegetative plant, the growing lateral shoots in a decapitated plant, the elongating subapical parts of the stem and the roots. The various metabolic sinks seemed to compete actively for this nutrient, therefore P-32 accumulation in any particular growing region of the plant was taken as an indicator of nutrient utilization potential of that part. The stem apex of an intact plant seemed to loose its dominance with the increasing age of the plant. The loss of apical dominance was almost complete during the reproductive phase of the plant, during which the upper lateral shoots initiated growth. Their growth, however, was inhibited soon because of competition with the other developing sinks, viz., the flower and the fruit. The amount of soluble carbohydrates in various parts of the pea plant followed essentially the same pattern as did P-32 accumulation. These distribution patterns were apparently correlated with the growth of the plant.     

环境因子对香根草生长习性的影响

环境因子对香根草生长习性的影响夏汉平,敖惠修,何道泉（中国科学院华南植物研究所,广州５１０６５０）ＥｆｆｅｃｔｏｆＥｎｖｉｒｏｎｍｅｎｔａｌＦａｃｔｏｒｓｏｎＶｅｔｉｖｅｒＧｒａｓｓＧｒｏｗｔｈ．￥ＸｉａＨａｎｐｉｎｇ;ＡｏＨｕｉｘｉｕ;ＨｅＤａｏｑ...     

Identification of a male sterile gene Ms in Brassica rapa L.

Molecular Breeding - Flowering time is an important agronomic trait, which is of great significance to the plant growth process. Salicylic acid (SA) is a key hormone that regulates plant growth and...     

Nitrogen fixation byAlnus viridis (Chaix) DC.

Summary InAlnus viridis nodule growth relative to plant growth was inversely related to the quantity of nitrate added to nutrient solutions. Nodulated plants showed maximum growth when grown independently of supplied nitrogen and made better growth in its absence than unnodulated plants at any level of added nitrogen. Low levels of nitrate caused a depression of growth of nodulated plants, apparently by suppressing both nitrogen fixation and nodule growth. Nodules in nitrogen-free sand culture fixed atmospheric nitrogen at a rate of 6.6 mg/day/g nodule. Phosphorus deficiency was induced by low levels of phosphate and resulted in small plants with dark-green foliage. Root and nodule growth as a percentage of total plant growth and the percentage of total accumulated plant nitrogen below ground were greater at a root temperature of 11°C than 21°C. Thus at low root temperature processes other than nitrogen fixation were limiting to plant growth. Excised nodules were exposed to an N ₂ ¹⁵ -enriched atmosphere. A positive correlation between rate of nitrogen fixation and temperature was obtained, with optimum fixation occurring at about 20°C. It was shown that in spite of decreasing mean temperatures with increase in altitude, rate of nitrogen fixation by nodules of plants growing in the field increased with increase in altitude. This latter trend was deduced to be a reflection of the extent to which the field sites were nitrogen deficient in relation to climatically possible growth.     

Plants and gravity. Special issue

This issue of the Journal of Plant Growth Regulation explores the effects of gravity on plant growth and development from several perspectives. Most of the review papers consider plants and gravity from the viewpoint of ground-based laboratory research, and several papers consider gravitropism, the directed growth in response to gravity, in some detail. However, another approach to study the effects of gravity on plant is to effectively remove the force due to gravity. A very dramatic way to accomplish this goal is through the free-fall conditions achieved by spacecraft in low Earth orbit, so some of the authors have reviewed recent advances in spaceflight research with plant systems.     

Kinematics of plant growth.

Many of the concepts and equations which have been used in the study of compressible fluids can be applied to problems of plant development. Growth field variables, i.e. functions of position in the plant and of time, can be specified in either Eulerian (spatial) or Lagrangian (material) terms. The two specifications coincide only when the spatial distribution of the variable is steady, and steady patterns are most likely to emerge when an apex is chosen as origin of the co-ordinate system. The growth field itself can be described locally by the magnitude and orientation of the principal axes of the rate of strain tensor and by the vorticity tensor. Material derivatives can be calculated if the temporal and spatial variation in both growth velocity, u (rate of displacement from a material origin), and the variable of interest are known. The equation of continuity shows the importance of including both growth velocity, u, and growth rate, ▽ ·u in estimates of local biosynthesis and transport rates in expanding tissue, although the classical continuity equation must be modified to accommodate the compartmentalized distributions characteristic of plant tissue. Relatively little information on spatial variation in plant organs can be found in the botanical literature, but the current availability of interactive computer graphics equipment suggests that analysis of the spatial distribution of growth rates at least is no longer difficult.     

Burkholderia sp. SCMS54 reduces cadmium toxicity and promotes growth in tomato

Cadmium (Cd) can enter soil through the use of fertilisers, calcareous, pesticides and industrial and/or domestic effluents. Cd can leach into groundwater and be taken up by plants, potentially leading to reductions in plant growth and yield. In soil, plant roots interact with heavy metal (HM)‐tolerant microorganisms that may promote plant growth. Soil microorganisms may also be able to solubilise or mobilise soil metals, thereby acting as bioremediators. A better understanding of the interaction among plants, metals, microorganisms and soil will lead to improved plant tolerance. Two multi‐tolerant bacteria from the Burkholderia genus were isolated from Cd‐contaminated and Cd‐uncontaminated soil of a coffee plantation. In addition to its high tolerance to Cd, the strain SCMS54 produces indole‐acetic acid (IAA), solubilises inorganic phosphate and produces siderophores, demonstrating its potential to contribute to beneficial plant–microorganism interactions. When interacting with tomato plants exposed to Cd, the bacterium led to decreases in plant peroxide and chlorosis levels, promoted relative plant growth and decreased the root absorption of Cd, resulting in increased plant tolerance to this highly toxic HM. The results indicated that the inoculation of tomato plants with Burkholderia sp. SCMS54 promotes better growth in plants cultivated in the presence of Cd. This phenomenon appears to be attributed to a mechanism that decreases Cd concentrations in the roots via a beneficial interaction between the bacteria and the plant roots.     

Plant growth enhancing effects by a siderophore-producing endophytic streptomycete isolated from a Thai jasmine rice plant (Oryza sativa L. cv. KDML105)

An endophytic Streptomyces sp. GMKU 3100 isolated from roots of a Thai jasmine rice plant (Oryza sativa L. cv. KDML105) showed the highest siderophore production on CAS agar while phosphate solubilization and IAA production were not detected. A mutant of Streptomyces sp. GMKU 3100 deficient in just one of the plant growth promoting traits, siderophore production, was generated by inactivation of a desD-like gene encoding a key enzyme controlling the final step of siderophore biosynthesis. Pot culture experiments revealed that rice and mungbean plants inoculated with the wild type gave the best enhancement of plant growth and significantly increased root and shoot biomass and lengths compared with untreated controls and siderophore-deficient mutant treatments. Application of the wild type in the presence or absence of ferric citrate significantly promoted plant growth of both plants. The siderophore-deficient mutant clearly showed the effect of this important trait involved in plant–microbe interaction in enhancement of growth in rice and mungbean plants supplied with sequestered iron. Our results highlight the value of a substantial understanding of the relationship of the plant growth promoting properties of endophytic actinomycetes to the plants. Endophytic actinomycetes, therefore, can be applied as potentially safe and environmentally friendly biofertilizers in agriculture.     

Plant growth and architectural modelling and its applications. Preface

Over the last decade, a growing number of scientists around the world have invested in research on plant growth and architectural modelling and applications (often abbreviated to plant modelling and applications, PMA). By combining physical and biological processes, spatially explicit models have shown their ability to help in understanding plant–environment interactions. This Special Issue on plant growth modelling presents new information within this topic, which are summarized in this preface. Research results for a variety of plant species growing in the field, in greenhouses and in natural environments are presented. Various models and simulation platforms are developed in this field of research, opening new features to a wider community of researchers and end users. New modelling technologies relating to the structure and function of plant shoots and root systems are explored from the cellular to the whole-plant and plant-community levels.     

Transformation of Solanum nigrum L. protoplasts by Agrobacterium rhizogenes

Summary Solanum nigrum protoplasts were co-cultivated with Agrobacterium rhizogenes harboring agropine-type Ri plasmid (pRi15834). A large number of transformed calli were obtained on Murashige and Shoog's (MS) medium lacking plant growth regulators. Frequency of transformation was about 3.5×10^–3. In most of the calli, hairy roots appeared on MS medium without plant growth regulator. When the hairy roots were cut into segments and subcultured on MS medium lacking plant growth regulators, calli were readily formed. Plantlets were regenerated by transferring those calli to MS medium supplemented with 1 mg/l zeatin and 0.2 mg/l naphthaleneacetic acid. Frequency of plant regeneration was about 70%.     

The plant cell wall. * Rose JKC, ed 2003. * Oxford: CRC Press. {pound}99.50 (hardback). * 381 pp.

Cell walls have long been recognized as important and uniquefeatures of plant cells, contributing not only to the architectureof plant organs but also to the control of growth, to the exclusionof pathogens and to the production and transmission of signallingmolecules. Gross measurements of plant cell composition establishedlong ago that the plant devotes a large     

Fish emulsion as a food base for rhizobacteria promoting growth of radish (Raphanus sativus L. var. sativus) in a sandy soil

Commercial fish emulsion was evaluated as a plant growth medium and as a nutrient base to enhance radish (Raphanus sativus L. var. sativus) growth by bacterial and actinomycete isolates. Six bacterial isolates including three actinomycetes were selected from a screening of 54 bacteria (including 23 actinomycetes) based on their ability to produce plant growth regulators (PGRs) and to colonize radish roots. These isolates were tested in the presence and absence of autoclaved or non-autoclaved fish emulsion or inorganic fertilizers. The nutrient contents and types and levels of PGRs in tissues of treated plants were assayed to determine the basis of growth promotion. Fish emulsion was found to support plant growth in a sandy soil as effectively as an applied inorganic fertilizer. The plant growth promotion by bacterial and actinomycete isolates was most pronounced in the presence of autoclaved or non-autoclaved fish emulsion than in the presence of the inorganic fertilizers. The bacterial and actinomycete isolates were capable of producing auxins, gibberellins and cytokinins and appeared to use fish emulsion as a source of nutrients and precursors for PGRs. PGR levels in planta following combined treatments of the bacterial and actinomycete isolates and fish emulsion were found to be significantly enhanced over other treatments. The effect of fish emulsion appears to be more related to its role as a nutrient base for the bacterial and actinomycete isolates rather than to the increased activity of the general microflora of treated soil. This is the first report of fish emulsion as a nutrient base for plant growth promoting rhizobacteria. These results also indicate that the successful treatment can be effective and economical for horticultural production in sandy soils such as those found in the United Arab Emirates where fish emulsion is already in use as a substitute or supplement for inorganic fertilizer.     

Influence of metribuzin on the Rhizobium leguminosarum--lentil (Lens culinaris) symbiosis.

The effects of the triazine herbicide metribuzin (Sencor) on the lentil (Lens culinaris Medic.) - Rhizobium leguminosarum biovar viciae symbiosis were studied in Leonard jars and growth pouches. Lentils inoculated with Rhizobium leguminosarum strain 128C54 or 128C84, and noninoculated lentils grown in plant nutrient solution supplemented with 5 mM KNO3, had metribuzin applied to the plants at either 8 or 13 days after planting. When sprayed at 8 days, metribuzin had a significant (p less than or equal to 0.05) negative effect on plant weight, number of nodules, taproot growth, and acetylene reduction activity. Five to 10 days after spraying, the plants began to recover from the inhibitory effects. When spraying was delayed to 13 days after planting, metribuzin had little effect on plant growth. The R. leguminosarum strain used as inoculant affected the degree of inhibition of lentil growth and the rate of plant recovery. Less than 0.2% of foliarly applied metribuzin was translocated to the root. Thus the detrimental effects of metribuzin application to lentils were mainly due to direct effects on the plant, which resulted in indirect effects on nodulation and nitrogen fixation.     

Cytotoxic effects of maleic hydrazide.

Since 1950, maleic hydrazide (MH) has been introduced into agriculture as a major commercial herbicide and a depressant of plant growth in numerous circumstances such as suppression of sprouting of vegetables and stored food crops, control of sucker growth on tobacco plants, ratardation of flowering and prolongation of dormancy period. Since 1951 MH has been known as an effective chromosome-breaking agent in higher plants, in sharp contrast with its low effect on the chromosomes and general health of tested mammals. The selectivity of action of MH in plants and animals was obviously the main reason of low interest devoted to the chemical by people working the field of environmental mutagenesis. In early works the inhibitory effects of MH on plant growth were mainly considered to result from the suppression of plant metabolism (inhibition of enzymic activity) and interference of the compound with plant hormones and growth regulators. More recently, numerous experiments performed with various plant species have shown that MH acts as an inhibitor of the synthesis of nucleic acids and proteins. Similar results have been obtained with animal tumour cells. The chromosome-breaking effect of MH on plant chromosomes resembles very closely the chromosome-breaking properties of alkylating agents and other mutagenic compounds such as mitomycin C. MH-induced chromosomal aberrations have also been recorded in grasshoppers, fish and mice, although tests with some mammalian cell lines gave negative results. Among higher plants, selective sensitivity to the toxic effects of MH is well proved. This phenomenon seems to be due to the differential ability of various plant species to detoxicate the chemical. Plants can break down MH into several products, one of which, hydrazine, is a well-known mutagen and carcinogen. MH does not seem to be toxic to bacteria and fungi. The compound is degraded by soil microflora and hence can be utilized as a source of nitrogen nutrition. MH proved to be of low toxicity to mammals, but in some instances it decreased the fertility of rats. The reported carcinogenic effects of MH in mice and rats raise the question of its risks to man.     

USE OF GROWTH CHARACTERISTICS IN STUDIES OF MORPHOLOGIC RELATIONS. I. SIMILARITIES BETWEEN EPIBLAST AND COLEORHIZA

Foard , Donald E., and Alan H. Haber . (Oak Ridge Natl. Lab., Oak Ridge, Tenn.) Use of growth characteristics in studies of morphologic relations. I. Similarities between epiblast and coleorhiza. Amer. Jour. Bot. 49(5): 520–523. Illus. 1962.—We compared the characteristics of wheat epiblast, coleorhiza, and leaves during germination and seedling growth. Although the epiblast and coleorhiza grow without cell division during germination, they sometimes produce hairs that resemble root hairs but are different in form and mode of origin from leaf hairs. Despite the similar orientation of the epiblast and leaves with respect to the main axis of the plant, during growth the epiblast changes shape such that the axis of greater linear extension per millimeter is perpendicular to the main axis of the plant, whereas leaves change shape such that the greater rate of linear extension per millimeter is parallel to the main axis of the plant. Indoleacetic acid treatment produces excessive and disorganized growth of both the epiblast and coleorhiza but retards leaf growth. Gibberellic acid stimulates, whereas (2-chloroethyl)trimethylammonium chloride retards leaf growth. Neither substance significantly affects epiblast or coleorhiza. We conclude that the epiblast is not leaf-like, but together with the coleorhiza forms a single, continuous structure. This paper illustrates how a wide variety of growth characteristics may be used to complement classical anatomic approaches in studies of morphologic relations.