基于形态学及多基因位点的枸杞褐斑病病原鉴定

枸杞Lycium barbarum Mill.是一种药食两用的名贵中药材,褐斑病是2010年在甘肃省枸杞种植区发生的由无性态类真菌新种枸杞小黑梨孢Stigmella lycii引起的新病害,据2015年-2018年调查,该病害已扩展至甘肃省各枸杞种植区,常年发病率45%～65%,严重度2～3级。本研究首次对枸杞小黑梨孢有性态形态进行描述,并结合分子生物学方法,确定该病病原菌的系统发育地位,为该病的防治提供一定的理论依据。枸杞褐斑病菌在离体培养条件下和越冬病叶上均可形成有性态。子囊壳球形至亚球形,大小185.6μm×176.6μm,有喙,喙的大小为(35.7～53.6)μm×(32.0～53.55)μm;子囊袋状,大小(103.2～165.7)μm×(15.7～22.4)μm,含8个子囊孢子;子囊孢子砖格状,大小(25.9～36.5)μm×(9.4～14.1)μm,平均31.2μm×12.3μm,具(4～)6～7个纵隔和1～3个横隔。通过ITS、LSU、RPB2和EF1-α多基因位点联合构建系统发育树,确定该菌为子囊菌门格孢腔菌目格孢腔菌科真菌。秋末冬初清洁田园,减少来年初侵染源,是有效防治枸杞褐斑病的关键措施。     

对虾白斑综合征病毒研究概况

对虾白斑综合征病毒(WSSV)引起世界范围内养殖对虾的急性、致死性传染病,造成对虾养殖业的巨大损失,在我国这种情况尤为严重。WSSV是同一类紧密相关的无包埋体类杆状病毒,与杆状病毒并无同源性。2001年,中国和荷兰科学家分别报道了WSSV的全基因组DNA序列,启动了WSSV后基因组研究。已有多种检测方法用于WSSV的检测和致病机理的研究。WSSV感染宿主谱广,以多种传播途径感染宿主,目前还没有用于病毒增殖的细胞系,但已有成熟的动物模型,从而方便了对WSSV的研究。本文就该病毒的命名、病毒特性、检测方法、病毒感染增殖、感染宿主、传播途径及感染动物模型等方面的研究现状和进展作一综述。     

大枫子与马钱上的叶斑类真菌病害

报道1986～1989年在泰国大枫子、海南大枫子和印度马钱上发现的9种叶斑类真菌病害的症状、病原菌及病情、分布。9种病原菌中,大枫子褐斑病菌(Ascochyta hydnocarpi S.M.Lin et P.K.Chi)、马钱叶枯病菌(Didymosphaeria strychnoris S.M.Lin et P.K.Chi)、马钱叶斑病菌(Microsphaeropsis strychoris S.M.Lin et P.K.Chi)和马钱轮纹褐斑病菌(Mycosphaerella strychnoris S.M.Lin et P.K.Cki)是新种。     

糖槭叶枯病发病规律及防治

糖槭叶枯病 Phyllosticta negundinis病菌孢子放散开始期和高峰期与每年的温、湿度变化有关。病害发生严重程度与降雨量关系密切 ,降雨早且量大时病害严重。病菌以分生孢子器和分生孢子在病叶上越冬 ,通过气流传播成为翌年初侵染源。喷洒 70 %甲基托布津可湿性粉剂 10 0 0倍液和 75%百菌清可湿性粉剂 80 0倍液均能收到较好的效果     

一次防治大豆灰斑病籽粒灰斑

通过室内及田间大豆不同生育期接种试验证明，籽粒感染灰斑病的关键时期是Ｒ３－Ｒ５期．Ｒ２期以前侵染不造成籽粒斑驳，据此提出一次防治大豆籽粒灰斑病的关键时期为Ｒ２－Ｒ４期．     

Morphological characterization of the interaction between Diplocarpon rosae and various rose species

Blackspot, caused by Diplocarpon rosae , is the most severe and ubiquitous disease of garden roses, but information is lacking about genotype-specific forms of resistance and susceptibility of the host. Macro- and microscopic analyses of 34 rose genotypes with a defined monoconidial culture black spot inoculum identified susceptible and resistant rose genotypes and further genotype-specific subdivisions, indicating the presence of partial forms of resistance and different resistance mechanisms. In total, eight interaction types were characterized, five representing compatible (types 1–5) and three representing incompatible interactions (types 6–8). The incompatible interactions were characterized by the lack of any visible fungal structures beneath the cuticle (type 8), single-cell necroses (type 7) or necroses of larger cell clusters (type 6), the latter two types with penetration hyphae and haustoria in epidermal cells.     

Pelargonium flower-break and pelargonium line pattern viruses in the Netherlands; purification,antiserum preparation,serological identification,and detection in pelargonium by ELISA

Two viruses, detected frequently in the Netherlands in pelargonium, were identified by serology and test plant reactions. Antisera were prepared and an ELISA procedure was developed to detect the viruses in pelargonium.One of the viruses, PFBV-N, proved to be pelargonium flower-break virus. With the antiserum to PFBV-N, it could be detected reliably throughout the year inPelargonium zonale Springtime Irene.The other virus, PLPV-N, was serologically closely related to pelargonium line pattern virus (PLPV) and to pelargonium ring pattern virus (PRPV), as were an old virus isolate from Saturnus, collected in the Netherlands in 1971 (L128), and PLPV isolates from Yugoslavia (PLPV-Y) and Denmark (PLPV-D). There were only minor differences in host-plant reactions between the virus isolates. Based on these tests, PLPV and PRPV are considered as isolates of the same virus, for which, for practical reasons, the name pelargonium line pattern virus is proposed.PLPV could be reliably detected by ELISA inP. zonale Springtime Irene and Amanda throughout the year with only a few exceptions. InPelargonium peltatum Tavira, however, reslts were erratic due to uneven distribution of virus in the plant. Best results were obtained when petioles of fully expanded leaves were tested.     

Detection of airborne inoculum of Leptosphaeria maculans and Pyrenopeziza brassicae in oilseed rape crops by polymerase chain reaction (PCR) assays

The potential use of DNA-based methods for detecting airborne inoculum of Leptosphaeria maculans and Pyrenopeziza brassicae , both damaging pathogens of oilseed rape, was investigated. A method for purifying DNA from spores collected using Hirst-type spore samplers and detecting it using polymerase chain reaction (PCR) assays is described. For both pathogens, the sensitivities of the DNA assays were similar for spore-trap samples and pure spore suspensions. As few as 10 spores of L. maculans or P. brassicae could be detected by PCR and spores of both species could be detected against a background of spores of six other species. The method successfully detected spores of P. brassicae collected using spore traps in oilseed rape crops that were infected with P. brassicae. Leptosphaeria maculans spores were detected using spore traps on open ground close to L. maculans -infected oilseed rape stems. The potential use of PCR detection of airborne inoculum in forecasting the diseases caused by these pathogens is discussed.     

Movement of Xanthomonas campestris pv. vitians in the stems of lettuce and seed contamination

Xanthomonas campestris pv. vitians , the causal agent of bacterial leaf spot of lettuce (BLS), can be seedborne, but the mechanism by which the bacteria contaminates and/or infects lettuce seed is not known. In this study, the capacity of X. campestris pv. vitians to enter and translocate within the vascular system of lettuce plants was examined. The stems of 8- to 11-week-old lettuce plants were stab-inoculated, and movement of X. campestris pv. vitians was monitored at various intervals. At 4, 8, 12 and 16 h post-inoculation (hpi), X. campestris pv. vitians was recovered from 2 to 10 cm above (depending on stem length) and 2 cm below the inoculation site. Xanthomonas campestris pv. vitians was also recovered from surface-disinfested stem sections of spray-inoculated plants. Together, these results are consistent with X. campestris pv. vitians invading and moving systemically within the vascular system of lettuce plants. To investigate the mechanism of seed contamination, lettuce plants at the vegetative stage of growth were spray-inoculated with X. campestris pv. vitians and allowed to develop BLS. Seed collected from these plants had a 2% incidence of X. campestris pv. vitians external colonization, but no bacteria were recovered from within the seed.     

Genetic variability within Phaeoisariopsis griseola from Central America and its implications for resistance breeding of common bean

The genetic and virulence variability of 112 isolates of Phaeoisariopsis griseola , collected from various locations in Central America, were studied using seven random amplified polymorphic DNA (RAPD) primers and 12 common-bean differential genotypes. Broad molecular diversity ( H  = 0·92) among isolates was found using RAPD markers. Fifty pathotypes were identified on 12 differential bean genotypes, 29 of which were represented by only one isolate. Only 18 pathotypes were found in two or more countries. Pathotype 63-63 was the most virulent and caused leaf spots on all 12 common-bean differential genotypes. Comparison of virulence phenotypes and RAPD profiles to known Andean P. griseola isolates confirmed that all isolates belonged to the Mesoamerican group. Pairwise comparison between individual RAPD loci showed that the majority were in gametic phase linkage disequilibrium, revealing that P. griseola maintains a genetic structure that is consistent with asexual reproduction. The molecular and virulence diversities of P. griseola isolates from Central America imply that using single resistance genes to manage angular leaf spot is inadequate and stacking resistance genes may be necessary to manage the disease effectively.