Effects of peach branches returning on autotoxins and microbes in soil and tree growth of peaches

Aims This study aimed to investigate the effects of branch returning on the growth of peach (Amygdalus persica Chunmei/Maotao) saplings, soil enzyme activity, and soil contents of phenolic acids and amygdalin, thereby providing scientific evidence against the application of branch returning for peach trees. Methods One-year-old potted peach tree (Amygdalus persica Chunmei/Maotao) was used in this study with four agricultural treatments applied, including soil coverage by fragmented peach tree branches (fragment treatment;1.5 and 22.5 g·kg^-1) and applying leachate solutions of peach tree branches to soil (leachate treatment; 1.5 and 22.5 g·kg^-1). No branch addition was used as control (CK). Solid phase extraction, high performance liquid chromatography (HPLC), biological high-throughput sequencing was used to determine the content of autotoxic substances, and microbial community structure in soil. Soil coverage and leachate solution treatments of 30 g and 450 g branches applied to the peach trees were described as 1.5 and 22.5 g·kg^-1, respectively in this paper.Important findings Compared with CK, the phenolic acid and amygdalin contents significantly increased after both fragment and leachate treatments in high quantities (22.5 g·kg^-1). Soil microbial community structure altered in both treatments, with the proportion of fungi (particularly Agaricomycetes, Tubeufia and Cystofilobasidiaceae) increased significantly and bacteria decreased accordingly. Invertase activity in both high-quantity treatments exceeded that in the CK significantly. The activity of catalase and urease was higher at first and then decreased relative to CK under high-quantity fragment and leachate treatments. Specifically, the effect of leachate treatment on enzyme activity was higher than the fragment treatment in the short term. Chlorophyll content, ground diameter (diameter of 5 cm from the ground) growth and net photosynthesis rate of plants were lower in high-quantity fragment and leachate treatments than those in CK, with earlier retardation of new shoot growth. We observed an increase in soil phenolic acids and enzymes in treatments in normal pruning quantity, while no inhibition effect was found on the tree growth. In conclusion, autotoxins (such as phenolic acid and amygdalin) inhibited the growth of peach trees both directly and indirectly through changing soil enzyme activity and microbial community.     

Mechanical stresses of primary branches: a survey of 40 woody tree and shrub species

Land plants have evolved a large number of growth forms and each plant species has a unique morphology. For many tall plants, main stems serve the function of vertical growth while primary and higher order branches are responsible for lateral growth for greater light interception. Herein we search for a mechanical constant for primary branches. Primary branches were sampled from 40 species of trees and shrubs. Among the species sampled, branch lengths ranged from 1.8 to 12.2 m, weights from 0.056 to 16.6 kg, base diameters from 17 to 150 mm, bending moments from 7.1 to 2,200 N-m, and section moduli from 0.039 to 29.0 × 10⁻³ m³. Primary branches of all 40 tree and shrub species exhibited relatively constant bending stresses along each branch. Moreover stress values among the 40 species were relatively constant at about 11 MPa (mean = 11.1 MPa [range 5.2–18.9]; standard deviation = 3.3 MPa). Furthermore, primary branches without secondary branches attached (1) had similar bending moment distributions as tapered cantilever beams, (2) exhibited relatively constant slope values of stress versus length among all species (stresses increased linearly with length), and (3) exhibited both relatively constant density and relatively constant taper within each species. We conclude that the relatively constant stress of about 11 MPa of primary branches was due solely to the numbers, weights, and distributions of secondary branches and associated higher order branches along primary branches for the 40 plant species. To our knowledge, this is the first publication that shows a unifying mechanical constant for primary branches of plants.

Crown development in a pioneer tree, Rhus trichocarpa, in relation to the structure and growth of individual branches

Based on an allometric reconstruction, the structure and biomass-allocation patterns of branches and current-year shoots were investigated in branches of various heights in the pioneer tree Rhus trichocarpa, to evaluate how crown development is achieved and limited in association with height. Path analysis was conducted to explore the effects of light availability, basal height and size of individual branches on branch structure and growth. Branch angle was affected by basal height, whereas branch mass was influenced primarily by light availability. This result suggests that branch structure is strongly constrained by basal height, and that trees mediate such constraints under different light environments. Previous-year leaf area and light availability showed positive effects on current-year stem mass. In contrast, branch basal height and mass negatively affected current-year stem mass. Moreover, the length of stems of a given diameter decreased with increasing branch height. Therefore the cost of biomass investment for a unit growth in length is greater for branches of larger size and at upper positions. Vertical growth rate in length decreased with increasing height. Height-dependent changes in stem allometry and angle influenced the reduction in vertical growth rate to a similar degree.     

散孔材与环孔材树种枝干、叶水力学特性的比较研究

为揭示散孔材与环孔材树种树木水分生理特性的差异,选取了常见的3种散孔材落叶树种(毛白杨、法国梧桐和樱花)和3种环孔材落叶树种(刺槐、合欢和白蜡),研究了其枝干与叶水力学性质的差异及其协调性。结果表明:3种环孔材树种枝干横截面积基础上的最大比导水率(Ks-max)大于3种散孔材树种,但其木质部对空穴化的脆弱性(P50branch)高于散孔材树种,6种树木枝干的水分传输能力和抵抗空穴化能力之间存在一种相互制约的权衡关系。3种散孔材与3种环孔材树种的叶最大水力导度(Kl-max)和水力脆弱性(P50leaf)并无显著差异;对于3种散孔材树种,叶的水力脆弱性要高于枝干,但对3种环孔材树种而言,枝干的水力脆弱性要高于叶。6种树木枝干和叶的水力学性质(Kmax、P50)之间并无相关关系。这些结果表明:散孔材与环孔材树种的枝干水力学特性有明显差异,但叶水力学特性无差异;枝干与叶水力学性质之间是相互独立的。     

Relation between diameter and flow in branches of the bronchial tree

Two methods are described for calculating the value of the exponentx in the equation flow =k×diameter ^x , as pertaining to a branch of the bronchial tree. In the lungs from three humans, two dogs, one hamster, and one rat mean values ofx between 2.419 and 2.903 were found. They lie within the range of 2.333 to 3.0 predicted by the analysis of Uylings (Bull. Math. Biol. 39, 501–519, 1977).     

Resistance to paclitaxel increases the sensitivity to other microenvironmental stresses in prostate cancer cells

The microenvironment is central to many aspects of cancer pathobiology and has been proposed to play a role in the development of cancer cell resistance to therapy. To examine the response to microenvironmental conditions, two paclitaxel resistant prostate cancer (PCa) cell lines (stable and reversible) and one reversible heat resistant cell line were studied. In comparison to their parental cell lines, both paclitaxel resistant cell lines (stable and reversible) were more sensitive to microenvironmental heat, potentially yielding a synergistic therapeutic opportunity. In the two phenotypic cells repopulated after acute heat or paclitaxel treatments, there was an inverse correlation between paclitaxel and heat resistance: resistance to paclitaxel imparted sensitivity to heat; resistance to heat imparted sensitivity to paclitaxel. These studies indicate that as cancer cells evolve resistance to single microenvironmental stress they may be more sensitive to others, perhaps allowing us to design new approaches for PCa therapy.     

Angles of branching and diameters of branches in the human bronchial tree

The principle of minimal work requires that the conducting airways of the human lung should have a maximum radius for minimal resistance to gas flow. At the same time there is a requirement that the airways should have a minimal volume for economy of space. These two opposing requirements have been investigated mathematically, and a method for calculating the angle of branching which produces minimal volume has been derived. The relationship of the radii of the parent and daughter branches to produce minimal resistance has been similarly defined. By measurement of a bronchial cast from a human lung the extent to which the predicted optimum structure is realized in practice has been shown. The change in structure associated with change of function at the transition from conducting airway to diffusion zone has been demonstrated.     

Diameters, generations, and orders of branches in the bronchial tree

Studies of bronchial tree data by West et al. (J. Appl. Physiol. 60: 1089-1097, 1986) have shown that plots of mean diameter against generation, using log-log scales, can be represented by a power function with harmonic modulations. Other studies have shown that the mean diameter of the airways is exponentially related to order of branching. This paper demonstrates that both observations are compatible with a fractal model of branching, and because airway branching is fractal, this may explain why both are also true of the bronchial tree. Furthermore, the exponential relationship of mean diameter with generation in the larger airways, demonstrated by Weibel, is shown to result from the exponential relation of diameter with order in the fractal model.     

Cytokinin action in response to abiotic and biotic stresses in plants

The phytohormone cytokinin was originally discovered as a regulator of cell division. Later, it was described to be involved in regulating numerous processes in plant growth and development including meristem activity, tissue patterning, and organ size. More recently, diverse functions for cytokinin in the response to abiotic and biotic stresses have been reported. Cytokinin is required for the defence against high light stress and to protect plants from a novel type of abiotic stress caused by an altered photoperiod. Additionally, cytokinin has a role in the response to temperature, drought, osmotic, salt, and nutrient stress. Similarly, the full response to certain plant pathogens and herbivores requires a functional cytokinin signalling pathway. Conversely, different types of stress impact cytokinin homeostasis. The diverse functions of cytokinin in responses to stress and crosstalk with other hormones are described. Its emerging roles as a priming agent and as a regulator of growth‐defence trade‐offs are discussed.     

白及假鳞茎薄片诱导不定芽及快繁体系的构建

以白及(Bletilla striata)假鳞茎为外植体,根据上、中、下部位切取薄片,探索假鳞茎不同部位BA、NAA和TDZ对假鳞茎薄片诱导不定芽的影响,比较假鳞茎薄片不同厚度对褐化率和出芽数的影响,采用正交试验,研究了BA和NAA对不定芽增殖的效果,并对组培苗进行壮苗、生根和移栽。结果表明:假鳞茎的部位对诱导不定芽作用极显著,下部的出芽率显著高于上部和中部,BA和TDZ对诱导不定芽作用显著,NAA对诱导不定芽作用不显著。最佳诱导不定芽的方式为假鳞茎下部薄片在基本培养基+2.0 mg·L^-1BA+1.0 mg·L^-1TDZ的培养基上培养4周,出芽率为93.3%,出芽数为15个,厚度为1.6~2.0 mm的假鳞茎薄片其褐化率最低。最佳的增殖培养基为基本培养基+1.5 mg·L^-1BA+0.3 mg·L^-1NAA,增殖系数达4.3,平均苗高为7.8 cm。本研究成功建立了白及假鳞茎薄片诱导芽为关键技术的快繁技术体系,为白及种质资源创新奠定了基础。     

兴安落叶松的结实及其与短枝年龄结构的关系

继1989年以后,1991年大兴安岭林区兴安落叶松又出现一次结实,结实率平均为63.8％,且结实的林木多出现在过火的林地上。胸径28cm以上的林木结实率可达到80％以上,而且结实量多的林木绝大部分(85％以上)是树冠稀疏的。球果多集中于树冠的中部。短枝年龄结构格局对结实具有重要影响。短枝的数量以1、2年生最多,但结实的短枝主要属于3—7年生的短枝,一次种子丰收年,需要消耗大量的短枝数量,花芽中大部分为雄花,直接用于形成球果的雌花,一般尚不足20％。开花结实成熟年龄短枝的存蓄率愈高,其结实的潜力也愈大,出现种子年的可能性也愈大。     

Biomechanical features of eccentric cambial growth and reaction wood formation in broadleaf tree branches

Tree branches and stems have different physiological functions that work collaboratively to maximize light interception. Light penetration in tree crowns is controlled by the orientation of the branches. However, mechanisms of branch bending have not received the attention they deserve. This study approached the problem by investigating the growth strain distribution in the upper and lower sides of branches of broadleaf trees, estimating the bending tendency of branches, and observing the branch eccentricity and the distribution of gelatinous fibers. The strain distribution was compared between the branches of 11 species (including 8 examined species and 3 referenced species) and tilted stems of 37 species from both our data and previous reports. Compressive strain was generally observed on the lower side of branches, but little was measured in tilted stems. The pith eccentricity of branches was in a reverse pattern to the corresponding strain distribution of stems. The radial growth of branches was hypotropic in contrast to the epitropic eccentric growth in inclined trunks. Furthermore, on the upper side of branches, G-fibers within the fiber arcs formed in an intermittent manner rather than in the continual manner found in artificially inclined stems. The resultant upward bending moment might not suffice to counteract the branch’s own weight; therefore, most of the measured branches, differing from tilted stems, tended to bend downward. In conclusion, by comparing the biological and mechanical aspects of the strain distribution, bending tendency, and eccentricity, our experiments could discriminate the bending dynamics and role of G-fibers in tree branches from that of main stems.     

Apical control of branch growth and angle in woody plants

Apical control is the inhibition of a lateral branch growth by shoots above it (distal shoots). If the distal shoots are cut off to remove apical control, the lateral branch can grow larger and may bend upwards. Apical control starts when new lateral buds grow after passing through a period of dormancy. Buds initially break and produce leaves, then apical control is exerted and the lower (proximal) laterals stop growing. Apical control also inhibits growth of large, old branches. Gravimorphism and restricted water and nutrient transport can inhibit branch growth, but they are not primary mechanisms of apical control. Apical control may reduce branch photosynthesis. Under apical control allocation of branch-produced assimilate to the stem is relatively high, so low assimilates in the branch may limit branch growth even though hormone levels are adequate for growth. Hormones appear to be involved in apical control, but it is not known how. One role of hormones may be to maintain the strength of the stem sink for branch-produced assimilate. Upward bending of a woody branch after release from apical control requires both new wood production and production of wood cells that can generate an upward bending moment. Apical control inhibits radial growth of branches and, in some species, may regulate the production of wood with an upward bending moment.     

Extraction of arbutin and its comparative content in branches,leaves, stems,and fruits of Japanese pear Pyrus pyrifolia cv. Kousui

Arbutin is a tyrosinase inhibitor and is extensively used as a human skin-whitening agent. This study investigated the optimum conditions for extracting arbutin by ultrasonic homogenization from discarded branches pruned from Japanese pear (Pyrus pyrifolia cv. Kousui) trees. The arbutin content was measured in the branches and also in the leaves, stems, fruit peel, and fruit flesh.     

植物脂质应答逆境胁迫生理功能的研究进展

脂质是生命有机体中一类重要的化合物,可以参与并调节多种生命活动,并且在植物应答非生物胁迫(盐胁迫、干旱胁迫和温度胁迫等)过程中发挥着重要生理功能.但长期以来,对于脂质的研究多集中于动物细胞和医学领域,却疏于关注植物研究领域.借助于"组"学思想和生物技术的快速发展,脂质组学由于可以深层次、全面地揭示脂质的组分与功能,近年...     

Extrinsic and intrinsic influences on tree growth — anatomical analysis of spruce branches

Summary In order to differentiate between environmental (extrinsic) influences affecting tree growth, and those causing (intrinsic) temporary irregularities in a single tree, we investigated the anatomy of three branches of comparable size and age, taken from two 60-year-old European spruces [Picea abies (L.) Karst]. Wood depositions in five consecutive internodes (4–8) along the branches were analysed. Internodal cross-sections were evaluated to discover whether extrinsic factors may have influenced the structure of the cambial xylogenic derivatives, or whether structural variations were caused by intrinsic events. Features occurring in all three branches were evaluated as extrinsically influenced. Observations like earlywood disturbances, distribution of resin ducts, duplication of radial files, and increments with narrow or broad latewood bands were considered. The ratio of radial cell number to ring width was used to define the vigour of cambial growth during the years covered. Meteorological data of the growing periods (May–September 1981–1988) representing mean values of temperature, cloudiness, sunshine and precipitation were used to characterize weather conditions. They were considered as extrinsic influences, possibly affecting anatomical structures.     

Cystathionine in the brains of tree shrews and other mammals

The amino acid cystathionine is reported to show higher concentrations in the brains of man as compared to those of other species. Two-dimensional separation by electrophoresis-chromatography and densitometric analysis of amino acids showed that the brains of tree shrews had levels of cystathionine intermediate between those of man and other mammals such as tamarins, hedgehogs, and rats. Cystathionine may be involved in the circadian rhythms ofTupaiidae. In man a 10 fold variation in cerebral cystathionine is related to pathological conditions. Greater concentrations in white matter as compared to grey matter and other regional differences in brain tissue support the findings from inherited disorders that cystathionine plays an important role in the normal as well as the abnormal functioning of the brain.