Polymorphic DNA sequences of the fungal honey bee pathogen Ascosphaera apis

The pathogenic fungus Ascosphaera apis is ubiquitous in honey bee populations. We used the draft genome assembly of this pathogen to search for polymorphic intergenic loci that could be used to differentiate haplotypes. Primers were developed for five such loci, and the species specificities were verified using DNA from nine closely related species. The sequence variation was compared among 12 A.?apis isolates at each of these loci, and two additional loci, the internal transcribed spacer of the ribosomal RNA (ITS) and a variable part of the elongation factor 1α (Ef1α). The degree of variation was then compared among the different loci, and three were found to have the greatest detection power for identifying A.?apis haplotypes. The described loci can help to resolve strain differences and population genetic structures, to elucidate host-pathogen interaction and to test evolutionary hypotheses for the world's most important pollinator: the honey bee and one of its most common pathogens.     

Genetic variation in virulence among chalkbrood strains infecting honeybees

Ascosphaera apis causes chalkbrood in honeybees, a chronic disease that reduces the number of viable offspring in the nest. Although lethal for larvae, the disease normally has relatively low virulence at the colony level. A recent study showed that there is genetic variation for host susceptibility, but whether Ascosphaera apis strains differ in virulence is unknown. We exploited a recently modified in vitro rearing technique to infect honeybee larvae from three colonies with naturally mated queens under strictly controlled laboratory conditions, using four strains from two distinct A. apis clades. We found that both strain and colony of larval origin affected mortality rates. The strains from one clade caused 12-14% mortality while those from the other clade induced 71-92% mortality. Larvae from one colony showed significantly higher susceptibility to chalkbrood infection than larvae from the other two colonies, confirming the existence of genetic variation in susceptibility across colonies. Our results are consistent with antagonistic coevolution between a specialized fungal pathogen and its host, and suggest that beekeeping industries would benefit from more systematic monitoring of this chronic stress factor of their colonies.     

球囊菌侵染对意大利蜜蜂幼虫肠道免疫与解毒相关基因表达及蛋白质、脂质和糖类含量的影响

[目的]球囊菌Ascosphaera apis是一种真菌性病原体,可以侵染意大利蜜蜂Apis mellifera ligustica幼虫,导致蜂群患白垩病.本研究通过球囊菌侵染意大利蜜蜂幼虫,探究对意大利蜜蜂幼虫肠道免疫解毒相关基因表达及蛋白质、脂质和糖类含量的影响,分析球囊菌侵染胁迫下意大利蜜蜂免疫应答反应与营养物质...     

影响蜜蜂球囊菌侵染蜜蜂幼虫的因素及侵染过程观察

为探究蜜蜂球囊菌Ascosphaera apis只侵染封盖前后蜜蜂幼虫的原因及相关侵染机制, 本研究利用实验室饲养的意大利蜜蜂Apis mellifera ligustica幼虫, 给其接种球囊菌孢子, 探究不同接种量（0, 1.0×10², 1.0×10³, 1.0×10⁴, 1.0×10⁵ 和1.0×10⁶ 孢子/mL）、 接种时期（3, 4, 5和6龄幼虫）以及28℃低温处理6 h对蜜蜂球囊菌侵染的影响。同时对处于不同侵染阶段的蜜蜂幼虫做病理学切片, 探究球囊菌侵染的过程。结果显示： 球囊菌孢子接种量与蜜蜂的发病率密切相关（r=0.9883）, 蜜蜂幼虫对低于1.0×10³孢子/mL的侵染有抗性, 与不接孢子的对照组差异不显著（P>0.05）。蜜蜂不同龄期接种发病率的差异是因不同龄幼虫食量不同导致的摄入孢子剂量的不同引起的, 28℃低温处理能够显著提高处于幼虫到蛹转化期蜜蜂的发病率（P<0.05）, 而对取食阶段的蜜蜂幼虫没有影响。病理学研究表明, 在整个幼虫期, 摄入的孢子因中肠没有氧气不生长, 对幼虫没有致病性, 幼虫的取食和发育过程正常, 至幼虫期结束进入蛹期后, 蜜蜂的中后肠接通, 摄入的孢子伴随蜜蜂的蛹便进入后肠并在此迅速萌发生长, 在1~2 d内菌丝即突破体表, 导致蜜蜂死亡。蜜蜂球囊菌选择营养物质储存最多而防御能力较低的幼虫到蛹转化期侵染, 降低了侵染成本, 提高成功率。该研究阐明了蜜蜂球囊菌侵染蜜蜂的机制, 丰富了昆虫与病原菌之间相互作用的内容。     

意大利蜜蜂幼虫肠道内球囊菌及其纯培养的高表达基因差异分析

【背景】球囊菌是一种典型的蜜蜂真菌性病原,特异性地侵染蜜蜂幼虫。目前,有关球囊菌在侵染过程中的基因表达规律的信息极为有限。【目的】通过深入分析胁迫意大利蜜蜂(意蜂)幼虫肠道的球囊菌及其纯培养的高表达基因(HEGs)差异,探索球囊菌在胁迫意蜂幼虫肠道后期与胁迫前的基因表达规律。【方法】利用RNA-Seq技术对球囊菌胁迫的意蜂6日龄幼虫肠道(Aam T)及球囊菌纯培养(AaCK)进行深度测序,根据FPKM值筛选得到球囊菌的HEGs,进而通过GO(Gene ontology)及KEGG(Kyoto Encyclopedia of Genes and Genomes)富集分析、Venn分析对上述HEGs进行功能预测和生物学意义挖掘。【结果】AaCK与Aam T的转录组测序共得到105 447 578条原始读段(Raw reads),经过滤得到88 466 344条有效读段(Clean reads),两端平均Q20为97.50%,平均Q30为93.81%。GO富集分析结果显示,AaCK的HEGs富集于26个GO terms,基因富集数最多的是细胞(22 Unigenes),其次是细胞组件(22 Unigenes)和代谢过程(21 Unigenes);Aam T的HEGs富集于22个GO terms,基因富集数最多的是催化活性(23 Unigenes),其次是细胞进程(18 Unigenes)和代谢过程(18 Unigenes)。KEGG代谢通路(Pathway)富集分析显示,AaCK的HEGs富集在109个Pathways上,基因富集数最多的是核糖体(179 Unigenes),其次是氨基酸生物合成(70Unigenes)和碳代谢(62 Unigenes);Aam T的HEGs富集在114个Pathways上,基因富集数量最多的是核糖体(178 Unigenes),其次是碳代谢(116 Unigenes)和氧化磷酸化(112 Unigenes)。Venn分析结果显示,AaCK与Aam T共有的HEGs有260个,二者特有的HEGs分别为2 161个和4 445个。【结论】提供了胁迫意蜂6日龄幼虫肠道的球囊菌及其纯培养的HEGs表达谱,揭示了球囊菌在胁迫前和胁迫后期的基因表达规律,也为阐明球囊菌致病的分子机理提供了有益的信息和线索。     

蜜蜂微孢子虫在中国的自然种系构成初探

蜜蜂微孢子虫(Nosema apis及Nosema ceranae)是微孢子虫的典型代表之一,由它寄生蜜蜂所产生的疾病,称为蜜蜂微孢子虫病。通过目前国际上普遍使用的克隆16srRNA基因(16srDNA)的片段并测序的方法来进行蜜蜂微孢子虫在我国主要养蜂地区的分布情况。结果表明,在我国主要养蜂地区,造成大量西方蜜蜂患蜜蜂微孢子虫病的是东方蜜蜂微孢子虫Nosema ceranae,至今为止未发现过去我们广泛认定的西方蜜蜂微孢子虫Nosema apis。     

Genetic dissection of pathotype-specific resistance to ascochyta blight disease in chickpea (<Emphasis Type="Italic">Cicer arietinum</Emphasis> L.) using microsatellite markers

Ascochyta blight is an economically important disease of chickpea caused by the fungus Ascochyta rabiei. The fungus shows considerable variation for pathogenicity in nature. However, studies on the genetics of pathotype-specific resistance are not available for this plant-pathosystem. The chickpea landrace ILC 3279 has resistance to pathotype I and II of the pathogen. In order to understand the inheritance of pathotype-specific resistance in this crop, both Mendelian and quantitative trait loci analyses were performed using a set of intraspecific, recombinant inbred lines derived from a cross between the susceptible accession ILC 1272 and the resistant ILC 3279, and microsatellite markers. We identified and mapped a major locus (ar1, mapped on linkage group 2), which confers resistance to pathotype I, and two independent recessive major loci (ar2a, mapped on linkage group 2 and ar2b, mapped on linkage group 4), with complementary gene action conferring resistance to pathotype II. Out of two pathotype II-specific resistance loci, one (ar2a) linked very closely with the pathotype I-specific resistance locus, indicating a clustering of resistance genes in that region of the chickpea genome.     

Isogenic auxotrophic mutant strains in the <Emphasis Type="Italic">Aspergillus fumigatus</Emphasis> genome reference strain AF293

Aspergillus fumigatus is a ubiquitous fungus that is a frequent opportunistic pathogen in immunosuppressed patients. Because of its role as a pathogen, it is of considerable experimental interest. A set of auxotrophic isogenic strains in the A. fumigatus genome reference strain AF293 has been developed. Using molecular genetic methods, arginine and lysine auxotrophs were made by deletion of argB and lysB, respectively. Transformation of these auxotrophic strains with plasmids carrying argB or lysB, respectively, results in efficient integration at these loci. Finally, these strains are able to form stable diploids, which should further facilitate analysis of gene functions in this fungus. Furthermore, the development of this isogenic set of auxotrophic strains in the AF293 background will enable investigators to study this important opportunistic human pathogen with greater facility.     

Resistance to Chalkbrood disease in Apis mellifera L. (Hymenoptera: Apidae) colonies with different hygienic behaviour

Chalkbrood disease affects the larvae of honeybees Apis mellifera L. and is caused by the fungus Ascosphaera apis. Infected larvae die when they are stretched in the cap cell and suffer a gradual hardening that ends in a very hard structure (mummie). Several studies have demonstrated that colonies that express an efficient hygienic behaviour (uncapping of cell and subsequent removal of dead brood) exhibit a higher resistance to the disease. However, it remains unclear whether the advantage of hygienic colonies over less hygienic ones lies in the ability to remove mummies or in the early detection of infected larvae and its cannibalization before they harden. To elucidate this aspect, the hygienic behaviour of 24 colonies, which were subsequently provided with pollen cakes containig A. apis, was evaluated. The number of mummies and the number of partially cannibalized and whole larvae in uncapped cells were recorded. The most hygienic colonies controlled the disease better. These colonies also had a higher tendency to uncap cells that contained infected larvae and cannibalize them. The presence of A. apis in partially cannibalized and whole larvae in uncapped cells indicate that the advantage of hygienic colonies over less hygienic ones lies in the early detection of infected larvae death and their quick removal from the cell before they become mummies.     

Genetic Mapping Reveals Sophisticated Responses of Malus domestica to Botryosphaeria dothidea Isolates

Infection by the globally distributed pathogenic fungus Botryosphaeria dothidea (Moug.) Ces. et de Not. causes bot canker on the stems, branches and limbs or causes fruit ring rot (FRR) on the fruit in apple. To investigate the relationship between resistance to bot canker and FRR and among resistance mechanisms in response to different pathogen isolates, 34 major gene loci and six quantitative trait loci (QTLs) for bot canker and FRR resistance/susceptibility were genetically mapped on Malus genome using an F1 hybrid population (Jonathan × Golden Delicious) in 2008 and 2009. None of the QTLs for bot canker and FRR overlapped with the region of the major gene loci. Some of the FRR‐ and bot canker‐associated loci either coincided or overlapped, and some were independent, suggesting that the responses of different organs to the pathogen would be correlated but might deviate from each other. Some major gene loci and QTLs associated with different pathogen isolates of bot canker or, FRR were mapped to different regions of the genome. The results indicated that not only did the resistance mechanisms differ between bot canker and FRR but also that genetic differentiation occurred among pathogen isolates.     

Microsatellite markers for Sclerotinia subarctica nom. prov., a new vegetable pathogen of the High North

Eight polymorphic microsatellite loci were isolated from the ascomycete fungus Sclerotinia subarctica nom. prov. In Alaska, this pathogen causes white mold vegetable diseases sympatrically with the cosmopolitan and closely related Sclerotinia sclerotiorum. Eighteen alleles were observed across the 41 isolates tested and ranged from two to three alleles per locus. Together, the alleles from the eight polymorphic loci yielded only four haploid multilocus genotypes and exhibited significant linkage disequilibrium, reflecting extreme selfing and clonal vegetative reproduction.     

A cell culture model for Nosema ceranae and Nosema apis allows new insights into the life cycle of these important honey bee-pathogenic microsporidia

The population of managed honey bees has been dramatically declining in the recent past in many regions of the world. Consensus now seems to be that pathogens and parasites (e.g. the ectoparasitic mite Varroa destructor, the microsporidium Nosema ceranae and viruses) play a major role in this demise. However, little is known about host-pathogen interactions for bee pathogens and attempts to develop novel strategies to combat bee diseases have been hampered by this gap in our knowledge. One reason for this dire situation is the complete lack of cell cultures for the propagation and study of bee pathogens. Here we present a cell culture model for two honey bee-pathogenic microsporidian species, Nosema apis and N. ceranae. Our cell culture system is based on a lepidopteran cell line, which proved to be susceptible to infection by both N. ceranae and N. apis and enabled us to illustrate the entire life cycle of these microsporidia. We observed hitherto undescribed spindle-shaped meronts and confirmed our findings in infected bees. Our cell culture model provides a previously unavailable means to explore the nature of interactions between the honey bee and its pathogen complex at a mechanistic level and will allow the development of novel treatment strategies.     

温度、相对湿度和pH对蜜蜂球囊菌孢子萌发的影响

研究了温度、相对湿度和pH对蜜蜂球囊菌(Ascosphaeraapis)孢子萌发3个阶段(活化、膨大、产生萌发管)的影响．结果表明,孢子活化和膨大在15～40和(25～40)±0．5℃范围内受温度的影响不明显(P＞0．05);萌发管仅发生在25～37±0．5℃,最适温度位于(31～35)±0．5℃．相对湿度越大,越有利于孢子萌发,而相对湿度低于80％对孢子萌发极为不利．孢子萌发的3个阶段在pH为5～7．8时几乎不受pH变化的影响,而在pH值较低影响很大．可见,A．apis是一种高度专一的蜜蜂幼虫病原体．     

Phylogeographical analyses reveal global migration patterns of the barley scald pathogen Rhynchosporium secalis

A phylogeographical analysis of the scald pathogen Rhynchosporium secalis was conducted using nuclear DNA sequences from two neutral restriction fragment length polymorphism loci and the mating-type idiomorphs. Approximately 500 isolates sampled from more than 60 field populations from five continents were analysed to infer migration patterns and the demographic history of the fungus. Migration rates among continents were generally low, consistent with earlier reports of significant population subdivision among continents. Northern Europe was mainly a source population for global migration. We hypothesize that the pathogen only recently moved out of its centre of origin, resulting in founder populations that are reproductively isolated due to the contemporary absence of long-distance gene flow.     

Isolation of eight polymorphic microsatellite loci,using an enrichment protocol,in the phytopathogenic fungus Fusarium culmorum

We report the development of eight microsatellite markers in the haploid filamentous fungus Fusarium culmorum, a pathogen of numerous cereal crops. An enrichment protocol was used to isolate microsatellite loci, and polymorphism was explored with isolates of Fusarium culmorum and F. graminearum from natural populations collected from several French locations.     

ERECTA receptor-like kinase and heterotrimeric G protein from Arabidopsis are required for resistance to the necrotrophic fungus Plectosphaerella cucumerina

Arabidopsis resistance to the necrotrophic fungus Plectosphaerella cucumerina is complex and depends on the ethylene, jasmonic acid and salicylic acid signaling pathways. A quantitative trait loci (QTL) analysis of resistance to this fungus was performed using two populations of recombinant inbred lines. Three loci QRP1-QRP3 (for Quantitative Resistance to Plectosphaerella) were identified and mapped on chromosome 2 (QRP1 and QRP2) and 5 (QRP3). QRP1, the locus showing the strongest effect, was found to correspond to the ERECTA (ER) gene that encodes a receptor-like-kinase (RLK), which has been previously implicated in plant development, and resistance to the bacterium Ralstonia solanacearum. The leucine-rich repeat and the kinase domains of ERECTA were specifically required for resistance to P. cucumerina, as er mutant alleles impaired in any of these domains showed enhanced susceptibility to this fungus, but not to other virulent pathogens. The involvement of the ER-signaling pathway in resistance to P. cucumerina was supported by the fact that three mutants defective in this pathway, elk2, elk5 and elk4 (agb1-1), which encodes the beta-subunit of Arabidopsis heterotrimeric G protein, were also impaired in their resistance to this fungus. The putative function of the Arabidopsis heterotrimeric G protein in resistance to P. cucumerina suggested by the enhanced susceptibility of agb1-1 was corroborated by the demonstration that a null allele (gpa1-4) of the G protein alpha-subunit showed enhanced resistance to this pathogen. Deposition of beta-1,3-glucan callose at infection sites was specifically impaired in er-1 and agb1-1 mutants upon P. cucumerina inoculation. Taken together, these data suggest a putative function of ERECTA and heterotrimeric G protein in P. cucumerina perception.     

Isolation and characterization of codominant markers for the perennial canker fungal pathogen Neonectria ditissima

Neonectria ditissima is a fungal pathogen native to eastern North America that causes disfiguring cankers on numerous tree species, particularly birches (Betula spp.). In order to develop control strategies, fundamental knowledge of the pathogen's reproductive and dispersal dynamics is necessary. To undertake these studies, we developed genomic libraries enriched for clones containing microsatellites, and then designed primers flanking each locus. Of 34 loci that were screened, 11 were polymorphic among 38 isolates obtained from a single population. Gene diversities ranged from 0.05 to 0.862 with a mean of 0.409. These markers will be invaluable in population studies of this fungus.     

Highly polymorphic in silico-derived microsatellite loci in the potato-infecting fungal pathogen Rhizoctonia solani anastomosis group 3 from the Colombian Andes

Fourteen polymorphic microsatellite DNA markers derived from the draft genome sequence of Rhizoctonia solani anastomosis group 3 (AG-3), strain Rhs 1AP, were designed and characterized from the potato-infecting soil fungus R. solani AG-3. All loci were polymorphic in two field populations collected from Solanum tuberosum and S. phureja in the Colombian Andes. The total number of alleles per locus ranged from two to seven, while gene diversity (expected heterozygosity) varied from 0.11 to 0.81. Considering the variable levels of genetic diversity observed, these markers should be useful for population genetic analyses of this important dikaryotic fungal pathogen on a global scale.