豌豆根腐病研究进展

根腐病是豌豆根部的重要病害之一,在世界各地豌豆产区均有发生,是制约豌豆产业持续健康发展的因素之一。世界上尚未发现对根腐病完全免疫的豌豆品种,防治方法主要以农业防治和化学防治为主。本文从豌豆根腐病的发生与分布、病原菌的分类及特点、抗性鉴定及评价标准、种质资源、分子标记及防治策略等方面对国内外豌豆根腐病研究现状进行综述。并提出抗病育种和未来豌豆根腐病综合防治的研究方向。     

Low soil temperature reducing the yield of drip irrigated rice in arid area by influencing anther development and pollination

Drip irrigation can produce high rice yields with significant water savings; therefore, it is widely used in arid area water-scarce northern China. However, high-frequency irrigation of drip irrigation with low temperature well water leads to low root zone temperature and significantly reduce the rice yield compared to normal temperature water irrigated rice, for example, reservoir water. The main purpose of this paper is to investigate the effects of low soil temperature on the yield reduction of drip irrigated rice in the spike differentiation stage. The experiment set the soil temperatures at 18°C, 24°C and 30°C under two irrigation methods(flood and drip irrigation), respectively. The results showed that, at the 30°C soil temperature, drip irrigation increased total root length by 53% but reduced root water conductivity by 9% compared with flood irrigation. Drip irrigation also increased leaf abscisic acid and proline concentrations by 13% and 5%, respectively. These results indicated that drip irrigated rice was under mild water stress. In the 18°C soil temperature, drip irrigation reduced hydraulic conductivity by 58%, leaf water potential by 40% and leaf net photosynthesis by 25% compared with flood irrigation. The starch concentration in male gametes was also 30% less in the drip irrigation treatment than in the flood irrigation treatment at soil temperature 18°C. Therefore, the main reason for the yield reduction of drip irrigated rice was that the low temperature aggravates the physiological drought of rice and leads to the decrease of starch content in male gametes and low pollination fertilization rate. Low temperature aggravates physiological water deficit in drip irrigated rice and leads to lower starch content in male gametes and low pollination fertilization rate, which is the main reason for the reduced yield of drip irrigated rice. Overall, the results indicated that the low soil temperatures aggravated the water stress that rice was under in the drip irrigated environment, causing declines both in the starch content of male gametes and in pollination rate. Low temperature will ultimately affect the rice yield under drip irrigation.     

Drought and heat stress reduce yield and alter carbon rhizodeposition of different wheat genotypes

Drought and high temperature are major environmental stress factors threatening wheat production during grain filling stage resulting in substantial yield losses. Four wheat genotypes (Suntop, IAW2013, Scout and 249) were planted under two temperature levels (25 and 30°C) and two water levels (15% and 25% soil moisture content). Wheat yield, leaf δ¹³C, plant rhizodeposition, shoot biomass and root traits were examined. Low moisture (drought stress) and high temperature (heat stress) decreased the grain yield of all wheat genotypes, in particular 249, while combined drought and temperature stresses had the most pronounced negative effect on plant biomass and grain yield. Decreasing soil water availability decreased the allocation of plant‐derived C to soil organic carbon (SOC) and to microbial biomass through rhizodeposition. Leaf δ¹³C decreased with increased yield, suggesting that higher yielding genotypes were less water stressed and allocated less C to SOC and microbial biomass through rhizodeposition. Wheat genotypes with lower root/shoot ratios and thinner roots were more efficient at assimilating C to the grain, while genotypes with higher root/shoot ratios and thicker roots allocated more C belowground through rhizodeposition at the expense of producing higher yield. Therefore, improving these traits for enhanced C allocation to wheat grain under variable environmental conditions needs to be considered.     

滴灌紫花苜蓿根层水分稳定同位素特征分析

为了明确滴灌紫花苜蓿根层水分运移,进一步阐明滴灌节水机理,采用液态水稳定氢氧同位素技术,分析了滴灌紫花苜蓿根层水分稳定氢氧同位素分布特征。结果表明,紫花苜蓿根层水分稳定氢氧同位素在下层富集,且随土壤剖面深度的增加同位素富集量有增加的趋势。滴灌条件下,紫花苜蓿根层发育有较多细根,可迅速而高效地利用灌溉水,灌溉后紫花苜蓿对灌溉水的利用不明确偏向于某一深度土层,根层内各土层土壤水均有利用。灌溉前土壤干旱时,滴灌紫花苜蓿以30 cm上下土层土壤水作为主要水分来源的概率较高。     

不同立地类型根灌、滴灌水分扩散规律

为掌握根灌、滴灌在不同立地类型土壤中的水分扩散规律,通过不同灌水梯度试验,采用挖剖面和直观观测法,研究了根灌和滴灌在不同立地类型土壤水分的垂直和水平扩散规律。结果表明:风沙土中根灌、滴灌水分垂直扩散明显小于水平扩散,且灌水时间与扩散速率均呈负相关对数关系。沙质壤土中根灌水分垂直扩散明显小于水平扩散,滴灌则垂直扩散速率大于水平扩散,两者差异不明显;灌水时间与扩散速率呈负相关对数关系。灰棕漠土中根灌初期水分垂直扩散和水平扩散相同,随时间增大,水平扩散速率大于垂直扩散;滴灌则垂直扩散速率大于水平扩散,但两者差异不明显;灌水时间与扩散速率也呈负相关对数关系。总体来看,根灌在不同立地类型土壤中的水分无论垂直扩散速率还是水平扩散速率都表现为:沙质壤土风沙土灰棕漠土;滴灌则无论水平扩散速率还是垂直扩散速率都表现为:灰棕漠土风沙土沙质壤土,两者扩散规律明显不同。     

外源Ca~(2+)对莲藕幼苗盐胁迫的缓解效应

以莲藕H_2(花藕品种,盐敏感)为材料,利用NaCl与Ca(NO_3)_2处理3片立叶的幼苗,研究外源Ca~(2+)对缓解植株盐胁迫的生理作用。结果显示:采用NaCl处理后,叶片中叶绿素、可溶性蛋白含量和SOD活性显著降低,而细胞膜透性、丙二醛和脯氨酸含量升高;利用不同浓度的Ca~(2+)进行缓解处理,发现外源施加低浓度的Ca~(2+)后,叶片叶绿素、可溶性蛋白含量和SOD活性均显著提高,脯氨酸含量较之前升高幅度更大,而细胞膜透性和丙二醛含量后期显著降低,说明Ca~(2+)对缓解莲藕盐胁迫具有较好的效果。当Ca~(2+)浓度增加时,缓解作用不明显,甚至出现抑制效果。     

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。     

腐植酸浸种对盐碱胁迫下小麦根系抗氧化系统的影响

采用中性盐( NaCl)和碱性盐(NaHCO3)混合模拟不同浓度盐碱胁迫条件,对龙麦26和克旱16两种同基因型春小麦进行腐植酸浸种处理.分别测定根系氧离子自由基、丙二醛和谷胱甘肽含量,以及过氧化物酶超氧化物歧化酶活性,以探讨腐植酸对盐碱两种胁迫下小麦根系抗氧化系统的调控效应.结果表明:随着盐碱迫浓度的提高,小麦幼苗根系...     

Crop rotation sequencing to minimize yield losses of summer-irrigated lowland rice in Myanmar caused by the rice root-knot nematode Meloidogyne graminicola

Abstract

The effect of different rice-based crop rotation sequences on the population densities of Meloidogyne graminicola and on the yield of rice was evaluated in a microplot experiment under lowland rice field conditions. Ten treatments of cropping sequences were grown in four successive growing seasons: continuous growing of the susceptible rice cultivar Thihtatyin (rice-rice-rice-rice), four treatments of 1- season crop rotation sequences (rice-rice-chickpea-rice, rice-rice-black gram-rice, rice-rice-soybean-rice, rice-rice-cowpea-rice), and five treatments of 2-season crop rotation sequences (groundnut-rice-chickpea-rice, green gram-rice-black gram-rice, cowpea-rice-soybean-rice, sesame-rice-cowpea-rice, sunflower-rice-sesame-rice). Population densities of M. graminicola recovered from the rice plants and the nematode multiplication factors (Mf) in the soil in the continuous rice cropping sequence (rice-rice-rice-rice) was the highest among the ten cropping sequences. Lowest nematode Mf in the soil was observed in the 2-season crop rotation sequence sunflower-rice-sesame-rice and the highest was observed in the 1-season crop rotation sequence rice-rice-cowpea-rice among the nine crop rotation sequences. Highest rice yield was obtained in the 2-season crop rotation sequences green gram-rice-black gram-rice, sesame-rice-cowpea-rice and sunflower-rice-sesame-rice, which were about 2 times higher compared with the 1-season crop rotation sequences and about 3 times higher compared with the continuous rice cropping sequence.