腥黑粉菌属一新种

本文报道了从意大利进口兔尾草(Lagurus ovatus L.)上截获的腥黑粉菌属一新种——兔尾草腥黑粉菌(Tilletia laguri G.M.Zhang,G.X.Lin & J.R.Deng),同时讨论了该种与近似种的区别,文中对其形态特征有拉丁文和汉文描述,并附有图片。主模式标本保存在深圳动植物检疫局真菌标本室,等模式标本分别保存在德国蒂宾根大学范基黑粉菌标本馆(HUV)、中国科学院微生物研究所真菌标本室和华南农业大学植保系真菌标本室。     

Characteristics of the Infection of Tilletia laevis Kühn (syn. Tilletia foetida (Wallr.) Liro.) in Compatible Wheat

Tilletia laevis Kühn (syn. Tilletia foetida (Wallr.) Liro.) causes wheat common bunt, which is one of the most devastating plant diseases in the world. Common bunt can result in a reduction of 80% or even a total loss of wheat production. In this study, the characteristics of T. laevis infection in compatible wheat plants were defined based on the combination of scanning electron microscopy, transmission electron microscopy and laser scanning confocal microscopy. We found T. laevis could lead to the abnormal growth of wheat tissues and cells, such as leakage of chloroplasts, deformities, disordered arrangements of mesophyll cells and also thickening of the cell wall of mesophyll cells in leaf tissue. What’s more, T. laevis teliospores were found in the roots, stems, flag leaves, and glumes of infected wheat plants instead of just in the ovaries, as previously reported. The abnormal characteristics caused by T. laevis may be used for early detection of this pathogen instead of molecular markers in addition to providing theoretical insights into T. laevis and wheat interactions for breeding of common bunt resistance.     

小麦网腥黑粉菌冬孢子总DNA提取方法比较

目的：研究提取不同时期小麦网腥黑粉菌冬孢子总DNA的最佳方法。方法：应用改良过的四种方法（CTAB法、SDS-CTAB法、SDS法和尿素法）对小麦网腥黑粉菌冬孢子总DNA进行提取。结果：提取当年小麦网腥黑粉菌冬孢子DNA,纯度（OD260/OD280）：CTAB法〉SDS-CTAB法〉SDS法〉尿素法=1.876〉1.7815〉1.7789〉1.6095;产率（μg/g）：SDS-CTAB法〉SDS法〉尿素法〉CTAB法=796.25〉664〉306〉291.5。提取15年的小麦网腥黑粉菌冬孢子DNA,纯度（OD260/OD280）：CTAB法〉SDS-CTAB法〉SDS法〉尿素法=1.91795〉1.8876〉1.65985〉1.55925;产率（μg/g）：尿素法〉CTAB法〉SDS法〉SDS-CTAB法=1529.25〉799〉687.25〉372.5。结论：SDS-CTAB法是提取当年小麦网腥黑粉菌冬孢子DNA的最佳方法。CTAB法是提取15年的小麦网腥黑粉菌冬孢子DNA的最佳方法。     

Determination of variability in monosporidial lines of Tilletia indica by RAPD analysis

Genetic variability in 23 monosporidial lines developed from five isolates of Tilletia indica causing Karnal bunt of wheat isolated from four wheat growing states of India was determined by using 19 rapid amplified polymorphic DNA (RAPD) markers. Amplification profile generated with all the 19 primers produced 3–16 numbers of bands of 1.5–5 kb size. High level of polymorphism (95.2%) suggested wide range of variability. Maximum Jaccard's similarity coefficient (80%) was observed between KB2MsB and KB2MsC followed by KB5MsC and KB5MsE with 75% similarity, whereas it was minimum between KB3MsA and Kb4MsB (47%). The dendrogram derived from the fingerprint analysis with 19 RAPD primers by using UPGMA showed different levels of genetic similarity among monosporidial lines. At 35% genetic similarity, the monosporidial lines were grouped in two clusters. Some primers, viz., OPN-1, OPN-6, OPN-9, OPN-12, OPN-13, OPN-18, OPM-2, OPM-8, OPM-10, OPB-8, OPB-17 and OPB-20 showed 100% polymorphism. The RAPD fingerprint generated by OPN-1 and OPM-3 were analysed and showed high range of variation in genetic make-up of monosporidial lines.     

A comparison of inoculation techniques for assessment of germplasm susceptibility to Karnal bunt (Tilletia indica) disease of wheat

Three inoculation techniques for Karnal bunt (Tilletia indica) disease of wheat were compared: 1) boot inoculation - injection of inoculum with a hypodermic syringe into the boot; 2) spray inoculation - inoculum sprayed at growth stages between heading and anthesis, and 3) cotton wool inoculation - small pieces of cotton wool saturated in inoculum placed either inside the floret or between the spikelet and rachis. Each inoculation technique was assessed using susceptible cultivars to determine the optimum inoculum concentration, the ideal plant growth stage and the humidity requirements for successful infection.
Boot inoculation did not require high humidity and gave reliable infection with low secondary sporidia concentrations (1000–10 000/ml). The ideal plant growth stages for inoculation were early-boot and mid-boot. Spray inoculation required high secondary sporidia concentrations (50 000/ml) and 48 h of high humidity, but infection was initiated over a range of growth stages throughout heading and anthesis. Cotton wool inoculation gave low levels of infection at growth stages throughout heading and anthesis, even with high secondary sporidia concentrations (100 000/ml).     

小麦印度腥黑粉菌与近似种的形态学比较*

利用光学显微镜和扫描电镜对小麦印度腥黑粉菌及其近似种的形态学特征进行了系统研究。T. indica和T. horrida不同菌株冬孢子大小变化范围均较大。在所研究的种中,T. indica与T. walkeri最近似,前者冬孢子大小平均值比后者略大,分别为:38.35?5.92祄和32.86?1.53祄。T. indica与其它具有疣状或刺状突起的腥黑粉菌:T. horrida, T. barclayana, T. setariae, T. opaca, T. sumatii和T. savilei等区别明显,T. indica冬孢子大小平均值明显大于这些腥黑粉菌,前者大于30祄,后者则小于30祄, T. indica孢壁纹饰与这些腥黑粉菌也有一定区别。应用光学显微镜和扫描电镜,能将T. indica与除T. walkeri之外的其它近似种区别开,但在区别T. indica与T. walkeri方面则有一定的局限性。     

Development and validation of microsatellite markers for Karnal bunt (Tilletia indica) and loose smut (Ustilago segetum tritici) of wheat from related fungal species

Simple sequence repeats (SSRs) are preferred molecular markers because of their abundance, robustness, high reproducibility, high efficiency in detecting variation and suitability for high‐throughput analysis. In this study, an attempt was made to mine and analyse the SSRs from the genomes of two seed‐borne fungal pathogens, viz Ustilago maydis, which causes common smut of maize, and Tilletia horrida, the cause of rice kernel smut. After elimination of redundant sequences, 2,703 SSR loci of U. maydis were identified. Of the remaining SSRS, 44.5% accounted for di‐nucleotide repeats followed by 29.8% and 2.7% tri‐ and tetranucleotide repeats, respectively. Similarly, 2,638 SSR loci were identified in T. horrida, of which 20.2% were di‐nucleotide, 50.4% tri‐ and 20.5% tetra‐nucleotide repeats. A set of 65 SSRs designed from each fungus were validated, which yielded 23 polymorphic SSRs from Ustilago and 21 from Tilletia. These polymorphic SSR loci were also successfully cross‐amplified with the Ustilago segetum tritici and Tilletia indica. Principal coordinate analysis of SSR data clustered isolates according to their respective species. These newly developed and validated microsatellite markers may have immediate applications for detection of genetic variability and in population studies of bunt and smut of wheat and other related host plants. Moreover, this is first comprehensive report on molecular markers suitable for variability studies in wheat seed‐borne pathogens.     

同步分子检测两种腥黑粉菌近似种Tilletia bromi和T.fusca

早熟禾是优良的牧草和草坪草,近年来,从进境早熟禾上多次截获一种腥黑粉菌,但一直被鉴定为禾草腥黑粉菌Tilletia fusca。通过比较研究,作者已将该菌种名改为雀麦腥黑粉菌T.bromi。依据T.bromi和T.fusca的序列差异位点设计了6对引物,成功建立了适合菌丝检测的T.bromi和T.fusca的双重PCR方法和适合冬孢子检测的套式双重PCR方法,检测灵敏度达到10pg/μL,为早熟禾腥黑粉菌鉴定提供了快速、可靠的检测方法。     

Determination of genetic and pathological variance among Tilletia indica isolates and monosporidial lines using PCR based markers and host differentials

Karnal bunt of wheat caused by Tilletia indica is an important international quarantine disease in many countries. In this investigation, genetic and pathological variation among the 10 isolates and 15 monosporidial (Ms) lines belonged to different locations of North-West India was studied. Depending upon the pathogenic potential, most virulent and least aggressive isolate was found from Chaksu (Rajasthan) and Tarau (HP), which scored coefficients of infection 70.98 and 6.22, respectively, on susceptible host genotype HD 2009 under artificially inoculated conditions. Fifteen Ms lines were inoculated in 20 combinations. Most virulent compatible combination was found KB2MsD?×?KB6MsA, which scored co-efficient of infection 74.91%. Out of 32 Inter Simple Sequence Repeats based molecular markers, 28 were polymorphic generating 192 reproducible bands for all the T. indica isolates and Ms lines in this study. A grouping analysis using the unrooted neighbour – joining method was consistent with DARwin software and winboot analysis and combination approach suggested that self-paired Ms lines exhibit narrow genetic diversity. This result will be useful for developing integrated strategies for disease management and breeding programmes for improvement of the varieties.