小麦赤霉病的药剂防治指标模型

经过推导,得出小麦赤霉病的两类药剂防治指标模型．在保证品质、收支有余的条件下,第一类模型附加产投比较佳、净收益最佳原则,第二类模型附加产投比最佳原则．灵敏度分析和合理性分析证明了模型的正确性．模型可做为小麦赤霉病药剂防治的决策工具．同时,给出了两类模型的BASIC计算程序．     

低聚糖提高小麦的抗病性及其应用于防治小麦赤霉病的研究

赤霉菌丝细胞壁和小麦细胞壁低聚糖片断在小麦黄化苗中能有效地诱导小麦抗毒素积累,经诱导产生的小麦抗毒素对小麦霉菌有明显的抑菌作用。采用同样的低聚糖片断处理大田小麦,能明显提高感病小麦品种绵阳１１号和宁麦６号对小麦赤霉病的抗病能力。用不同浓度的低聚糖片断处理麦穗,２０ｕｇ／ｍｌ赤霉菌壁低聚糖是适宜的浓度,能使宁麦６号的病穗率减少４４．９％,使绵阳１１号减少２６．９％。２０ｕｇ／ｍｌ,小麦细胞壁低聚糖喷洒宁麦六号,杨麦１５８和川育１２号,能有效地提高这些品种抗小麦赤霉病的能力,防效分别达到９０．０％、８１·１％和８８．９％。     

应用11371复合剂防治人参锈腐病的研究

人参锈腐病是栽培参的主要病害,发病率一般在60—80％,对栽培参的损失很大。由于该病是土传病害,而且致病菌复杂,多年来尚无较好的防治方法。本文介绍了使用抗生素11371为主的复合药剂防治人参锈腐病的情况;几年来田间防效稳定在45％以上,最高防效可达70％,并且用药当年可增产15％左右。     

小麦对赤霉病抗性不同品种的SOD活性

本研究对9个赤霉病抗性不同小麦品种采用赤霉病菌分生孢子悬浮液以单花针注法进行了田间和温室抗病性鉴定;测定了各品种的胚性愈伤组织和盛花期麦穗分别经赤霉病菌毒素和分生孢子接种前后SOD活性的变化。结果表明,各品种SOD活性与其对赤霉病抗性呈极显著的正相关。接种后寄主的SOD活性均有提高,抗病品种比感病品种提高幅度大,且有新的同工酶带出现。抗病品种望水白比感病品种Alondra“S”多出两条SOD同工酶谱带。SOD在小麦抗赤霉病上可能起积极作用,其活性有可能作为鉴定小麦抗赤霉病的一种生理生化指标。     

海南火龙果细菌性腐烂病的病原鉴定及田间药剂筛选

细菌性腐烂病是近年在海南火龙果上普遍发生的一种病害。为有效防治该病害,阻止其进一步扩散和蔓延,本研究从临高县东英镇采集病样多份,经病原分离、形态和分子鉴定、致病性测定以及田间药效试验,对其进行了病原鉴定和田间药剂的筛选。结果表明:代表菌株Huo30能产生黄色素,使火龙果致病,与成团泛菌(Pantoea agglomerans)相似性100%,为火龙果细菌性腐烂病的病原菌。4种药剂中,53.8%氢氧化铜WG1000倍液和47%春雷·王酮WP600倍液处理的防效最好,分别为71.05%和69.93%,与另外两个处理的防效差异显著;72%农用链霉素SP5000倍液处理的防效一般,在供试浓度下防效为65.14%;而2%春雷霉素AS600倍液处理对该细菌病害的防效最差,仅为63.31%。本研究结果为海南火龙果的防治提供了重要的理论依据。     

抗病小麦对脱氧雪腐镰刀菌烯醇的脱毒及产物的生物活性

抗赤霉病小麦品种苏麦3号、繁9能转化镰刀菌毒素脱氧雪腐镰刀菌烯醇(DON)成产物X,而感病小麦品种宁麦6号、徐州21无转化能力。产物X对小麦黄化芽鞘的伸长生长无抑制作用,而对禾谷镰刀菌分生孢子的萌发有明显抑制。说明抗性小麦品种对赤霉病菌毒素的脱毒是小麦重要的抗赤霉病机制。     

我国小麦赤霉病成灾原因分析及防控策略探讨

小麦是世界上三大粮食作物之一,是全球30亿以上人口的主粮。近年来,由于各种病虫害危害,全球小麦生产和粮食安全受到严重威胁,其中由禾谷镰刀菌引起的小麦赤霉病是小麦生产上重要的病害之一。此外,病菌会产生多种真菌毒素对人畜生命健康构成严重威胁。化学药剂的使用以及抗病品种的种植可以有效地控制小麦赤霉病的发生。但是,由于高产优质抗病品种匮乏、气候变暖等因素影响,小麦赤霉病在我国小麦主产区频繁暴发;同时,赤霉病菌抗药性产生致使化学农药的防控效果大大降低。从气候变化、耕作制度改变、小麦品种抗性及病菌抗药性等方面,分析了赤霉病暴发成灾的主要原因。在此基础上,结合当前赤霉病防控研究进展以及存在的科学问题,探讨该病害持续绿色防控的对策建议,以期为我国小麦赤霉病的防控研究提供参考。     

七种杀虫剂对小麦吸浆虫和麦蚜防治效果研究

【目的】明确25%吡蚜酮SC、3%甲氨基阿维菌素苯甲酸盐ME、25%噻虫嗪WG、14%氯虫·高氯氟ZC、15%高氯·毒死蜱EC、2.5%高效氯氟氰菊酯EW和40%毒死蜱EC 7种杀虫剂对小麦吸浆虫和蚜虫的防治效果,为科学、合理用药防治小麦害虫提供参考。【方法】采用喷雾法和剥穗调查法,研究它们对小麦吸浆虫成虫和麦蚜的防效,及防后对小麦吸浆虫幼虫危害损失的影响。【结果】参试药剂药后1 d对小麦吸浆虫成虫防效均高于90%,药后3~5 d防效为84.81%~93.93%,防后挽回损失76%以上;对麦蚜药后1、3、5 d防效分别高于75%、80%和85%。在供试的7种药剂中,15%高氯·毒死蜱EC药后3~5 d对两种害虫防效、挽回吸浆虫危害均超过90%,应用效果最好;其次为25%噻虫嗪WG和40%毒死蜱EC,药后3~5 d对吸浆虫防效高于90%、对麦蚜防效分别高于86%和90%,挽回吸浆虫危害损失88%以上。【结论】供试药剂对小麦吸浆虫和麦蚜防效存在显著差异,15%高氯·毒死蜱EC对两种害虫防治效果最好。     

拮抗植物病原真菌链霉菌菌株ZH-356的鉴定及其生防评价

[目的]对实验室分离到的菌株ZH-356进行鉴定并评价其对植物病原真菌的生物防治效果,为研发针对植物真菌病害的生防菌剂提供理论指导。[方法]通过平板对峙法确定菌株ZH-356抗菌谱,并通过16S rRNA基因序列分析确定其种属,利用离体枝条的苹果树腐烂病菌感染预防试验和患腐烂病苹果树的防治试验评价其生防效果。[结果]菌株ZH-356鉴定为链霉菌属,与直丝紫链霉菌(Streptomyces rectiviolaceus)相似性最高,为99.71%。抗菌谱试验表明,菌株ZH-356对苹果树腐烂病菌、小麦赤霉病菌、小麦根腐病菌和番茄早疫病菌等多种植物病原真菌均具有较强的抑制作用,这种抑制作用可导致苹果树腐烂病菌菌丝变粗、交叉扭曲、分支变少且容易断裂。此外,ZH-356产生的抑菌活性物质对温度和酸碱度具有高度稳定性,并且该活性物质只存在于其胞内,只有当ZH-356遇到植物病原真菌时才会被分泌出来以抑制它们的生长。在离体枝条的苹果树腐烂病菌感染预防试验中,ZH-356对苹果树腐烂病防效可达94%以上,而在患腐烂病苹果树的防治试验中,ZH-356菌制剂对苹果树腐烂病的防效高达100%。[结论]链霉菌ZH-356抑菌谱广,对多种植物病原真菌均具有良好的拮抗活性,可作为防治植物真菌病害的生防菌株,为基于ZH-356菌株的生防菌剂的开发和防治苹果树腐烂病等植物真菌病害奠定了基础。     

基于MAS的小麦抗赤霉病育种材料抗性评价

为了提高黄淮海麦区小麦育种材料的赤霉病抗性,采用分子标记辅助选择的方法,将来自望水白的4个抗赤霉病主效QTL 3B-QTL、4B-QTL、5A-QTL和6B-QTL导入不同的感病背景中,在后代BC1F3和BC1F4株系中评价它们的抗病效应和农艺性状回复情况。结果表明:(1)导入4个抗病QTL株系的平均病小穗率和病粒率分别为12.2%和6.3%,而受体亲本则分别达到59.1%和44.2%,抗病性显著提高;(2)病小穗数和病粒率与穗长及株高极显著负相关,但与可育小穗数、百粒重、旗叶长和旗叶宽等农艺性状指标没有显著相关性。因此,通过导入抗病主效QTL可以显著改善感病材料的抗性,为进一步选育高产抗病品种提供基础材料。不良农艺性状的紧密连锁阻碍着抗赤霉病主效QTL的高效利用,需要通过继续回交或与其他品种杂交来打破这种遗传连锁关系。     

Spatiotemporal Dynamics of the Epidemic Transmission in a Predator-Prey System

Epidemic transmission is one of the critical density-dependent mechanisms that affect species viability and dynamics. In a predator-prey system, epidemic transmission can strongly affect the success probability of hunting, especially for social animals. Predators, therefore, will suffer from the positive density-dependence, i.e., Allee effect, due to epidemic transmission in the population. The rate of species contacting the epidemic, especially for those endangered or invasive, has largely increased due to the habitat destruction caused by anthropogenic disturbance. Using ordinary differential equations and cellular automata, we here explored the epidemic transmission in a predator-prey system. Results show that a moderate Allee effect will destabilize the dynamics, but it is not true for the extreme Allee effect (weak or strong). The predator-prey dynamics amazingly stabilize by the extreme Allee effect. Predators suffer the most from the epidemic disease at moderate transmission probability. Counter-intuitively, habitat destruction will benefit the control of the epidemic disease. The demographic stochasticity dramatically influences the spatial distribution of the system. The spatial distribution changes from oil-bubble-like (due to local interaction) to aggregated spatially scattered points (due to local interaction and demographic stochasticity). It indicates the possibility of using human disturbance in habitat as a potential epidemic-control method in conservation.     

Seed dispersal in a patchy environment with global age dependence

A model of seed population dynamics proposed by S. A. Levin, A. Hastings, and D. Cohen is presented and analyzed. With the environment considered as a mosaic of patches, patch age is used along with time as an independent variable. Local dynamics depend not only on the local state, but also on the global environment via dispersal modelled by an integral over all patch ages. Basic technical properties of the time varying solutions are examined; necessary and sufficient conditions for nontrivial steady states are given; and general sufficient conditions for global asymptotic stability of these steady states are established. Primary tools of analysis include a hybrid Picard iteration, fixed point methods, monotonicity of solution structure, and upper and lower solutions for differential equations.This work was supported in part by National Science Foundation Grants MCS-7903497 and MCS-790349701     

Invasion dynamics of epidemic with the Allee effect

Investigating the likely success of epidemic invasion is important in the epidemic management and control. In the present study, the invasion of epidemic is initially introduced to a predator-prey system, both species of which are considered to be subject to the Allee effect. Mathematically, the invasion dynamics is described by three nonlinear diffusion-reaction equations and the spatial implicit and explicit models are designed. By means of extensive numerical simulations, the results of spatial implicit model show that the Allee effect has an opposite impact on the invasion criteria and local dynamics when that on the different species. As the intensity of the Allee effect increases, the domain of epidemic invasion reduces and the system dynamics is changed from the stable state to the limit cycle and finally becomes the chaotic state when the susceptible prey with the Allee effect, but the domain expands and the system dynamics is changed from limit cycle to a table point when the predator is subject to the Allee effect. Results from the spatial explicit model show that the strong intensity of the Allee effect can lead to the catastrophic global extinction of all species in the case of that on the susceptible prey. While the predator with the Allee effect, the increased intensity of which makes spatial species reach a stable state. Furthermore, numerical simulations reveal a certain relationship between the invasion speed and spatial patterns.     

An SIR epidemic model with partial temporary immunity modeled with delay

The SIR epidemic model for disease dynamics considers recovered individuals to be permanently immune, while the SIS epidemic model considers recovered individuals to be immediately resusceptible. We study the case of temporary immunity in an SIR-based model with delayed coupling between the susceptible and removed classes, which results in a coupled set of delay differential equations. We find conditions for which the endemic steady state becomes unstable to periodic outbreaks. We then use analytical and numerical bifurcation analysis to describe how the severity and period of the outbreaks depend on the model parameters.      

Coexistence of multiple pathogen strains in stochastic epidemic models with density-dependent mortality

Stochastic differential equations that model an SIS epidemic with multiple pathogen strains are derived from a system of ordinary differential equations. The stochastic model assumes there is demographic variability. The dynamics of the deterministic model are summarized. Then the dynamics of the stochastic model are compared to the deterministic model. In the deterministic model, there can be either disease extinction, competitive exclusion, where only one strain persists, or coexistence, where more than one strain persists. In the stochastic model, all strains are eventually eliminated because the disease-free state is an absorbing state. However, if the population size and the initial number of infected individuals are sufficiently large, it may take a long time until all strains are eliminated. Numerical simulations of the stochastic model show that coexistence cases predicted by the deterministic model are an unlikely occurrence in the stochastic model even for short time periods. In the stochastic model, either disease extinction or competitive exclusion occur. The initial number of infected individuals, the basic reproduction numbers, and other epidemiological parameters are important determinants of the dominant strain in the stochastic epidemic model.     

An efficient simulation method for discrete-value controlled large-scale neuromyoskeletal system models

An efficient Euler-Adams hybrid integration scheme for simulating on the computer discrete-value controlled large-scale neuromyoskeletal system models is presented. If, as discussed in the model, the differential equations describing the recruitment and excitation dynamics of the muscular subsystem are independent of the corresponding contraction-dynamical state variables, they can be integrated separately over certain time intervals by a modified Euler routine that handles discontinuous right-hand sides efficiently. The resulting myostates can then be stored and used as continuous input values for the subsequent integration by an Adams predictor-corrector algorithm of the remaining contraction-dynamical and skeletomechanical state differential equations. With such an Euler-Adams hybrid integration routine one avoids the detrimental effects and efficiency losses associated with frequent stop-restart cycles of otherwise efficient Adams-type algorithms, which cycles are forced by discontinuities on the right-hand side of the myostate equations. In the example presented, a reduction in the execution time by a factor of about 5 could be achieved by implementing the proposed technique.     

Antagonistic action of Streptomyces pratensis S10 on Fusarium graminearum and its complete genome sequence

Wheat scab, mainly caused by Fusarium graminearum, can decrease wheat yield and grain quality. Chemical pesticides are currently the main control method but have an inevitable negative consequence on the environment and in food safety. This research studies a promising substitute, Streptomyces pratensis S10, which was isolated from tomato leaf mould and shows a significant inhibition effect on F. graminearum based on antagonism assays. The biocontrol mechanism is studied by enhanced green fluorescent protein labelling, quantitative real-time PCR, the Doskochilova 8 solvents system test and complete genome sequencing. Strain S10 can colonize in the wheat root, control wheat scab and decrease deoxynivalenol (DON) content. The control effects in vitro, planta and the plot experiments were 92.86%, 68.67% and 40.87% to 86.62%, respectively. S10 decreased DON content by inhibiting the mycelium growth and DON synthesis gene expression. The active substances of the S10 secondary metabolites had a high-temperature resistance and 29 putative biosynthetic gene clusters in its genome. The S10 control mechanism is multivariate, which shows potential in controlling wheat scab.     

Identification of introgressed segments conferring disease resistance in a tetrageneric hybrid of Triticum, Secale, Thinopyrum, and Avena.

Using genomic in situ hybridization to chromosomes, we identified introgressed segments in a tetrageneric hybrid of Triticum, Avena, Thinopyrum, and Secale, which conferred high resistance to leaf rust, stem rust, stripe rust, powdery mildew, and root rot to wheat. The disease-resistance traits of the hybrid originated from three wild related genera of Triticum, namely Avena, Thinopyrum, and Secale. The new breeding system that combined traditional wide hybridization with anther culture was efficient and rapid in creating wheat germplasms resistant to major diseases.     

禾谷镰刀菌粗毒素对不同抗性小麦品种成熟胚脱分化与再分化的影响

以5个赤霉病抗性水平不同的小麦品种为材料,研究了禾谷镰刀菌粗毒素对小麦成熟胚脱分化与再分化的影响.结果表明,小麦成熟胚愈伤组织的诱导率和分化率在品种间、毒素浓度间、毒素浓度×品种间差异极显著.低浓度（5 g/L）禾谷镰刀菌粗毒素能够促进抗性较强品种的出愈速度,高浓度禾谷镰刀菌粗毒素（10 g/L和15 g/L）对成熟胚愈伤组织的出愈速度起到抑制作用,随着浓度提高,抑制作用增强.成熟胚愈伤组织的诱导率和分化率随着禾谷镰刀菌粗毒素浓度升高而下降,品种的抗性越差下降幅度越大.10 g/L毒素浓度,5个品种成熟胚愈伤组织的SOD活性均比对照（0 g/L）增加;20 g/L毒素浓度,5个品种成熟胚愈伤组织的SOD活性均有所下降,抗性品种苏麦3号和郑9023的SOD活性仍高于对照,其它3个感性品种低于对照,SOD活性与小麦品种的赤霉病抗性水平存在一定关系.研究结果为小麦赤霉病抗性育种提供了一定的技术支撑.