Epidemiology of beet necrotic yellow vein virus in sugar beet at different initial inoculum levels in the presence or absence of irrigation

A field experiment was set up in 1988 to study the development of rhizomania disease of sugar beet at different inoculum levels of beet necrotic yellow vein virus (BNYVV) in soil. Five, tenfold different, inoculum levels were created by addition of the approximate amounts of 0, 0.5, 5, 50 and 500 kg infested soil per ha (the latter corresponding to 0.01% v/v calculated to the tillage layer). A drip irrigation treatment was applied to study the influence of soil moisture on disease. Susceptible sugar beet, cv. Regina, was grown for three consecutive years.In the first year, root symptoms were not observed, but BNYVV-infected plants were detected by ELISA in low numbers at all inoculum levels at harvest. After late drilling in 1989, high numbers of infected plants, up to 90–100% in plots with the highest inoculum level, were detected already in June. Root symptoms were also observed from June onwards. In both these years disease incidence increased in time and was significantly influenced by the initial inoculum level. In the third year, the whole field was heavily diseased, and only for the non-irrigated plots incidence differed for different initial inoculum levels. The expression of symptoms by BNYVV-infected plants was influenced by initial inoculum level, thus by the amount and timing of primary infection.Root weight at harvest was not affected, but sugar content decreased with increasing inoculum level already in 1988, leading to a reduction in sugar yield of 10% at the highest inoculum level. In 1989, both root weight and sugar content decreased progressively with increasing inoculum level, resulting in sugar yield reductions of 11–66% (down to approximately 3000 kg ha^–1) for low to high inoculum levels compared to the control. As the control plots became contaminated, all yields were low in 1990, still showing a decrease with increasing inoculum level in the non-irrigated plots, but an overall mean sugar yield of 3323 kg ha^–1 for the irrigated ones.Sodium and -amino nitrogen content of the root, additional quality parameters determining extractability of sucrose, showed an increase and decrease, respectively, with increasing initial inoculum level already in the first year. The relative differences in contents compared to those from the control were largest for Na content. A significant negative correlation was found between Na (mmol kg^–1 root) and sugar content (% of fresh weight); linear for 1988, exponential for 1989 and 1990.In spring 1989, the infestation of individual plots was assessed using a quantitative bioassay estimating most probable numbers (MPNs) of infective units of BNYVV per 100 g dry soil. The relationship between the MPns determined and root weight, sugar content and sugar yield at harvest could be described by Gompertz curves. The increase in disease incidence with increasing MPN in 1989 was adequately fitted with a logistic equation.     

Epidemiology of beet necrotic yellow vein virus in sugar beet at different initial inoculum levels in the presence or absence of irrigation: Dynamics of inoculum

Using field plots where rhizomania had not previously been detected, different inoculum levels of beet necrotic yellow vein virus (BNYVV) were created by application of infested soil. A susceptible sugar beet cultivar (cv. Regina) was grown for two consecutive years (1988 and 1989), in the presence or absence of drip irrigation. In soil samples taken in spring 1989, the different initial inoculum levels of 1988 could be distinguished using a quantitative bioassay estimating most probable numbers (MPNs) of infective units per 100 g dry soil. The first sugar beet crop resulted in a tenthousandfold multiplication of inoculum of BNYVV (viruliferousPolymyxa betae). Mean MPNs of BNYVV ranged from 0.6 and 7 per 100 g soil for the lowest inoculum level to 630 and 1100 per 100 g for the highest level, in plots without and with irrigation, respectively. In spring 1990, MPNs had again increased. In both years, the initial inoculum level of 1988 had a significant linear effect on log-transformed MPNs of BNYVV determined. Log-transformed MPNs for 1990 and 1989 showed a positive linear correlation, despite a decreasing multiplication ratio at higher inoculum levels. Drip irrigation during one or two years enhanced the increase in MPN of BNYVV, which was reflected by the enhancement of multiplication ratios at all inoculum levels. The totalP. betae population was also higher after growing two irrigated crops than after growing two non-irrigated ones.     

甜菜-甜菜坏死黄脉病毒互作过程中过氧化氢的积累与分布

以甜菜抗、感丛根病品种与甜菜坏死黄脉病毒互作体系为研究对象,检测不同体系间H₂O₂的产生和积累,并利用电镜细胞化学标记技术在亚细胞水平上对H₂O₂的空间分布定位,探讨H₂O₂积累和分布与甜菜抗丛根病性的关系。结果表明, 甜菜抗、感丛根病体系均出现大量H₂O₂,其中抗病体系的H₂O₂产生量明显高于感病体系。H₂O₂在抗病和感病体系中的分布位置基本相似,多分布在块根、叶脉细胞的液泡膜和质膜上,叶脉细胞间隙也有H₂O₂的分布,但不同体系间H₂O₂含量有着明显差异,感病体系H₂O₂沉积量明显弱于抗病体系。研究结果说明,H₂O₂产生量和分布与甜菜抗丛根病性有密切联系,H₂O₂参与了甜菜对病毒侵染的防御反应。     

Differential abundance of proteins in response to Beet necrotic yellow vein virus during compatible and incompatible interactions in sugar beet containing Rz1 or Rz2

Rhizomania, caused by Beet necrotic yellow vein virus (BNYVV), is an important disease affecting sugar beet. Control is achieved through planting of resistant varieties; however, following the introduction of Rz1, new pathotypes that overcome resistance have appeared. To understand how BNYVV overcomes resistance, we examined quantitative protein differences during compatible and incompatible interactions when sugar beet is infected with either a traditional A-type strain or with an Rz1 resistance breaking strain. Proteomic data suggest distinct biochemical pathways are induced during compatible and incompatible sugar beet interactions with BNYVV. Pathways including the detoxification of reactive oxygen species, UB/proteasome, and photosynthesis should be studied in more depth to characterize roles in symptom development.     

Identification of rhizomania-infected soil in Europe able to overcome <Emphasis Type="Italic">Rz1</Emphasis> resistance in sugar beet and comparison with other resistance-breaking soils from different geographic origins

Rhizomania, caused by Beet necrotic yellow vein virus (BNYVV), is vectored by Polymyxa betae. The disease can only be controlled by growing partially resistant sugar beets, which quantitatively reduce virus replication and spread. None of the known major resistance genes (Rz1, Rz2, Rz3), alone or in combination, are able to prevent BNYVV infection entirely. Here we report for the first time the identification of a Spanish soil, containing an A-type BNYVV with RNA 1-4, displaying Rz1 resistance-breaking abilities comparable to soils from the USA and to those from France containing the French (Pithiviers) P-type BNYVV with RNA 5. A resistance test with several soil samples vs. different sugar beet cultivars was conducted under standardised conditions. Sugar beets were analysed after 12 weeks of greenhouse cultivation for taproot weight, BNYVV and relative P. betae content. The soil samples from Spain, France and the USA produced high virus contents and strong rhizomania symptoms in Rz1 plants, indicative of resistance-breaking abilities. In addition, all resistance-breaking soil samples produced detectable virus concentrations in plant lateral roots of the Rz1 + Rz2 cultivar, and plants grown in the Spanish soil sample also had reduced taproot weight and displayed severe rhizomania disease symptoms. Additionally, the main pathogenicity factor P25, responsible for the formation of BNYVV symptoms, showed high sequence variability in the amino acid tetrad at position 67–70. The results suggest the geographically independent selection of BNYVV resistance-breaking isolates following the uniform cultivation of Rz1-containing sugar beet cultivars.     

新疆甜菜坏死黄脉病毒分离物的症状反应及核酸组分分析

利用症状反应和RT-PCR技术对12个采自新疆不同地区的甜菜坏死黄脉病毒(BNYVV)分离物进行比较研究,结果表明:12个BNYVV分离物在甜菜、番杏和昆诺阿藜上的症状反应无明显区别,均以黄斑为主;利用RT-PCR进行的核酸组分分析却有一定差异,不同地区的BNYVV分离物含有不同的RNA组分,塔城地区、奇台地区及石河子145团的BNYVV分离物核酸组分为RNA1、RNA2、RNA3和RNA4;库尔勒地区的BNYVV分离物核酸组分还含有RNA5;石河子有些地区的BNYVV分离物核酸组分只有RNA1和RNA2。     

Modelling the effect of temperature on the development of Polymyxa betae

Polymyxa betae is the fungal vector of beet necrotic yellow vein virus (BNYVV), which is the causal agent of the sugar beet disease rhizomania. The within-season dynamics of the fungus are a crucial factor in the occurrence and severity of rhizomania. Late infection of the host by viruliferous fungi enables host resistance to the virus to develop and hence limits crop damage. A previously published mechanistic model for the dynamics of Polymyxa betae is extended in this paper to incorporate the effect of temperature on the germination of resting spores, and on the latent periods between infection and the production of secondary zoospores and new resting spores. It is shown that, for UK temperature conditions, the effect of sowing date on infection is greater than that of year-to-year variations in temperature associated with a single representative sowing date. The variation in inoculum build-up predicted when temperature data from a range of soil types were used in the model agreed with field observations, where higher levels of infection are observed on sandy soils than on black fen peat soils. The difference was most distinct when daily maximum soil temperature values were used to drive the model rather than rolling 24-hour average values.     

Breeding for resistance to rhizomania in sugar beet: A review

Currently rhizomania is the most important disease in sugar beet worldwide, and attack can lead to serious yield losses. The disease is caused by beet necrotic yellow vein virus (BNYVV) that is transmitted by the soil-borne fungus Polymyxa betae. Breeding sugar beet cultivars with resistance to rhizomania is regarded as the most appropriate way to enable continued production of this crop in BNYVV-infested fields and also to slow the spread of the disease. Breeding for resistance started with selection by scoring disease symptoms in field experiments. The development of non-destructive greenhouse tests, with determination of the virus concentration in rootlets using ELISA, has greatly improved the efficiency of selection. In this paper the impact of scientific research on the progress in breeding cultivars with resistance to rhizomania is reviewed. This includes the distribution, composition, and pathogenicity of the virus, the sources of resistance to virus and vector, the genetics of virus resistance, progress with breeding methods, and the use of molecular markers and pathogen-derived resistance. The yields and quality characteristics of recently introduced resistant cultivars now equal those of the commercial susceptible cultivars. This revised version was published online in July 2006 with corrections to the Cover Date.     

Ecological aspects of transgenic sugar beet: transfer and expression of herbicide resistance in hybrids with wild beets

Summary An increasing number of genetically engineered cultivars of several crops is being experimentally released into the environment. In future, crops with new transgenic traits will probably play an important role in agricultural practice. The long-term effect of transgenes on community ecology will depend on the distribution and establishment of transgenic plants in the wild, on the sexual transfer of their new genes to the environment and on the potential ecological impact of the transgenic trait. The starting point was the use of transgenic sugar beet lines, Beta vulgaris subspec. vulgaris var. altissima DÖLL (Helm 1957), with transgenes coding for rhizomania and herbicide (BASTA^®) resistance. The first two questions to answer were: Can the transgenes be transferred via pollen to wild beets, Beta vulgaris subspec. maritima (L.) ARCANG. or cultivated relatives such as red beet or spinach beet and are they expressed in the hybrids? Can transgenes be monitored in young Beta vulgaris-hybrids? The experimental transfer of transgenes was conducted in 1993 at a field location in northern Germany. The beets were hand-pollinated with transgenic pollen. In a non destructive biotest, the hybrid seedlings were tested for herbicide resistance. Transgenic plants showed no noxious phenotypic effects whereas control plants developed leaf necroses. All herbicide resistant hybrids within the biotest were assumed to be transgenic.     

甜菜丛根病研究概况

从引发甜菜丛根病的致病病毒BNYVV、传播介体P.betae及环境影响因素等方面,对甜菜感染丛根病后的病症、鉴定、生理生化反应及其防治等研究进行了全面的综述。