香蕉褐缘灰斑病菌检测技术研究进展

香蕉褐缘灰斑病严重影响香蕉产量和品质,是香蕉生产上的重要生物灾害之一.香蕉褐缘灰斑病的早期诊断、检疫及防治的重要基础与前提是建立快速、灵敏的检测技术,从而准确及时鉴定出病原菌种类.本文介绍了香蕉褐缘灰斑病菌的种类和分类,概述了国内外香蕉褐缘灰斑病菌检测方法的研究进展,总结和归纳了传统、血清学、DNA指纹图谱、常规PCR...     

Sources of resistance to Pseudocercospora fijiensis,the cause of black Sigatoka in banana

Black Sigatoka, caused by Pseudocercospora fijiensis, is one of the most devastating diseases of banana. In commercial banana-growing systems, black Sigatoka is primarily managed by fungicides. This mode of disease management is not feasible for resource-limited smallholder farmers. Therefore, bananas resistant to P. fijiensis provide a practical solution for managing the disease, especially under smallholder farming systems. Most banana and plantain hybrids with resistance to P. fijiensis were developed using few sources of resistance, which include Calcutta 4 and Pisang Lilin. To broaden the pool of resistance sources to P. fijiensis, 95 banana accessions were evaluated under field conditions in Sendusu, Uganda. Eleven accessions were resistant to P. fijiensis. Black Sigatoka symptoms did not progress past Stage 2 (narrow brown streaks) in the diploid accessions Pahang (AA), Pisang KRA (AA), Malaccensis 0074 (AA), Long Tavoy (AA), M.A. Truncata (AA), Tani (BB), and Balbisiana (BB), a response similar to the resistant control Calcutta 4. These accessions are potential sources of P. fijiensis resistance and banana breeding programmes can use them to broaden the genetic base for resistance to P. fijiensis.     

Black Sigatoka leaf streaks of banana (Musa spp.) caused by Mycosphaerella fijiensis in Ethiopia

Journal of Plant Diseases and Protection - Sigatoka leaf streaks caused by Mycosphaerella spp. are the most destructive fungal diseases of bananas and plantains throughout the world. The disease is...     

Genetic structure of Mycosphaerella fijiensis populations from Australia, Papua New Guinea and the Pacific Islands

Single-copy restriction fragment length polymorphism (RFLP) markers were used to determine the genetic structure of Mycosphaerella fijiensis , the cause of black leaf streak (black Sigatoka) disease of banana and plantain, in the Torres Strait, Papua New Guinea (PNG), and the Pacific Islands. A moderate level of genetic variation was observed in all populations with genotypic diversity values of 60–78% of the theoretical maximum, and gene diversity ( H ) values between 0·269 and 0·336. All populations were at gametic equilibrium, and with the high level of genotypic diversity observed this indicated that sexual reproduction has a major role in the genetic structure of the M. fijiensis populations examined. Population differentiation was tested on several hierarchical scales. No evidence of population differentiation was observed between sites on Mer Island. A moderate level of population differentiation was observed within the Torres Strait, between Badu and Mer Islands ( F _ST = 0·097). On a regional scale, the greatest differentiation was found between the populations of the Torres Strait and the Pacific. Populations from these regions were more closely related to the PNG population than to each other, suggesting they were founded in separate events from the same population.     

Population differentiation in the banana leaf spot pathogen Mycosphaerella musicola, examined at a global scale

Single-copy restriction fragment length polymorphism (RFLP) markers were used to determine the genetic structure of the global population of Mycosphaerella musicola , the cause of Sigatoka (yellow Sigatoka) disease of banana. The isolates of M. musicola examined were grouped into four geographic populations representing Africa, Latin America and the Caribbean, Australia and Indonesia. Moderate levels of genetic diversity were observed for most of the populations ( H  = 0·22–0·44). The greatest genetic diversity was found in the Indonesian population ( H =  0·44). Genotypic diversity was close to 50% in all populations. Population differentiation tests showed that the geographic populations of Africa, Latin America and the Caribbean, Australia and Indonesia were genetically different populations. Using F _ST tests, very high levels of genetic differentiation were detected between all the population pairs ( F _ST > 0·40), with the exception of the Africa and Latin America-Caribbean population pair. These two populations differed by only 3% ( F _ST = 0·03), and were significantly different ( P  < 0·05) from all other population pairs. The high level of genetic diversity detected in Indonesia in comparison to the other populations provides some support for the theory that M. musicola originated in South-east Asia and that M. musicola populations in other regions were founded by isolates from the South-east Asian region. The results also suggest the migration of M. musicola between Africa and the Latin America-Caribbean region.     

应用RAPD标记技术鉴定香蕉褐缘灰斑病菌

采用Mycosphaerella fijiiensis和M.musicola的RAPD标记技术鉴定海南香蕉褐缘灰斑病菌,结果表明,分离自海南儋州、乐东、文昌、东方、澄迈、临高、琼海、昌江、琼山、三亚香蕉上的10个菌株均为M.fijiensis,引起香蕉黑叶条斑病。     

Variability in reproductive fitness and virulence of four Radopholus similis nematode populations associated with plantains and banana (Musa spp.) in Uganda

Burrowing nematodes (Radopholus similis) are among the most serious nematode pests affecting banana and plantain (Musa spp.). In Uganda, bananas, which are known locally as “matooke”, are the main staple. Radopholus similis populations collected in four banana-growing locations (Namulonge, Mbarara, Ikulwe and Mukono) were cultured monoxenically on carrot discs, and we compared the variability in reproductive fitness and virulence (as a function of time and inoculum level) of different populations of R. similis from Uganda. Their level of pathogenicity was determined by assessing the nematode reproductive ratio; that is, final population divided by the initial population. These in vitro experiments showed that the R. similis population from Mbarara had the highest reproduction ratio, while the population from Mukono had the lowest reproduction ratio. This assessment along with pathogenicity experiments on host Musa plants provides a means for defining pathogenicity groups among R. similis populations.     

Potential physical and chemical barriers to infection by the burrowing nematode Radopholus similis in roots of susceptible and resistant banana (Musa spp.)

Resistance in banana roots against the burrowing nematode Radopholus similis has been correlated in the past with the phenylpropanoid pathway of secondary metabolism, but quantitative chemical analyses to support histological data are lacking. Therefore, healthy and infected roots of two susceptible (Grande naine and Obino l'ewai) and three resistant cultivars (Yangambi km5, Pisang jari buaya and Calcutta 4) were extracted and chemically analysed for their lignin content and phenylpropanoid profile using a quantitative lignin assay, high performance liquid chromatography and liquid chromatography/mass spectrometry. Through histochemical staining phenylpropanoids were localized in root tissue. Compared to the susceptible cultivars, the resistant cultivars had constitutively significantly higher levels of lignin in the vascular bundle and cell-wall bound ferulic acid esters in the cortex. Infection-induced lignification was observed in the vascular bundles of all cultivars. The catecholamine dopamine was identified as a major metabolite in banana roots. Levels varied from 2·8 to 8·4 mg per g root fresh weight and were significantly higher in the resistant cultivars. Other compounds, tentatively identified as anthocyanidin-related, were present in high quantities and may, besides dopamine, make up the substrates for polyphenol oxidation products in necrotic tissue.     

漳州琯溪蜜柚果实黑斑病菌的分子鉴定

2008年从漳州采集到疑似由柑橘球座菌(Guignardia citricarpaKiely)引起的黑斑病症状的溪琯蜜柚(Citrus grandis(Linn.)Osbeck cv.guanxi-miyou)果实。使用柑橘球座菌(G.citricarpa)特异引物对该果实上的病斑进行PCR检测及序列分析。PCR检测结果表明从溪琯蜜柚果实病斑上扩增到约490bp的条带。序列分析结果表明,与已知的亚洲柑橘叶点霉(Phyllosticta citriasiana)、G.citricarpa和G.mangif-erae的相应序列同源性分别为99.8%、98.2%和94.0%。该序列含有部分的内转录间隔区1(ITS1)、5.8S核糖体RNA基因(5.8S rRNA)和部分的内转录间隔区2(ITS2)序列。结果表明,引起溪琯蜜柚果实病害的病原菌并不是G.citricarpa,而是一种新描述的病原菌——亚洲柑橘叶点霉(Phyllosticta citriasianaWulan-dari,Crous&Gruyter),该病原菌引起的病害称为柑橘褐斑病。     

Spatial variability of leaf wetness under different soil water conditions in rainfed jujube(Ziziphus jujuba Mill.) in the loess hilly region,China

Leaf wetness provides a wide range of benefits not only to leaves,but also to ecosystems and communities.It regulates canopy eco-hydrological processes and drives spatial differences in hydrological flux.In spite of these functions,little remains known about the spatial distribution of leaf wetness under different soil water conditions.Leaf wetness measurements at the top(180 cm),middle(135 cm),and bottom(85 cm)of the canopy positions of rainfed jujube(Ziziphus jujuba Mill.)in the Chinese loess hilly region were obtained along with meteorological and soil water conditions during the growing seasons in 2019 and 2020.Under soil water non-deficit condition,the frequency of occurrence of leaf wetness was 5.45%higher at the top than at the middle and bottom of the canopy positions.The frequency of occurrence of leaf wetness at the top,middle and bottom of the canopy positions was over 80%at 17:00?18:00(LST).However,the occurrence of leaf wetness at the top was earlier than those at the middle and bottom of the canopy positions.Correspondingly,leaf drying at the top was also latter than those at the middle and bottom of the canopy positions.Leaf wetness duration at the middle was similar to that at the bottom of the canopy position,but about 1.46-3.01 h less than that at the top.Under soil water deficit condition,the frequency of occurrence of leaf wetness(4.92%-45.45%)followed the order of top>middle>bottom of the canopy position.As the onset of leaf wetness was delayed,the onset of wet leaf drying was advanced and the leaf wetness duration was shortened.Leaf wetness duration at the top was linearly related(R²>0.70)to those at the middle and bottom of the canopy positions under different soil water conditions.In conclusion,the hydrological processes at canopy surfaces of rainfed jujube depended on the position of leaves,thus adjusting canopy structure to redistribute hydrological process is a way to meet the water need of jujube.