THE INFLUENCE OF INFECTION WITH NOSEMA APIS ON THE ACTIVITIES AND LONGEVITY OF THE WORKER HONEYBEE

Infection of the adult worker honeybee with Nosema apis reduces or obviates brood feeding and causes her to commence foraging earlier than a healthy bee. The length of foraging activity and the total length of life of infected bees is reduced.
In colonies infected with N. apis the rate of brood rearing is severely depressed during April, May and June, the degree of depression being proportional to the percentage infection.
Infection decreases during July, August and September, and consequently the rate of brood rearing increases, but the resulting addition in foraging population is usually too late to increase the honey crop.     

THE EPIDEMIOLOGY AND CONTROL OF NOSEMA DISEASE OF THE HONEY-BEE

The proportion of honey-bees infected with Nosema apis (Zander) declines in summer as the old infected bees die, for they cease to transmit their infection to the newly emerged individuals during the flying season. N. apis spores survive the summer on combs contaminated with infected faeces during the preceding winter. Although bees clean the combs during the summer, all infected material is not removed, and even well-used brood comb, which has been repeatedly cleaned by bees, can carry infection. Only a few bees may contract infection in the autumn from these faeces, but they join the winter cluster and initiate the next outbreak of the disease. Transferring a colony on to clean comb early in the spring or summer removes the source of the disease, and it then disappears when all the old infected bees die.
Old broodless comb can be sterilized quite simply by fumigation for a few days with the vapours of formalin or glacial acetic acid. Acetic acid is preferable, because it does not poison any honey or pollen in the combs. Formaldehyde can safely be used only with empty combs.
The autumn is the best time for treating colonies chemotherapeutically, because the combs are then cleanest and the few bees which are infected can be cured during the winter. The drug can be incorporated in the syrup normally fed to colonies in autumn, and there is no risk of seriously contaminating subsequent honey crops. However, such treatment cannot eliminate the disease because sufficient spores remain on the combs for the disease to start again when the drug supplied in the winter stores is exhausted.     

Worker genetic diversity and infection by Nosema apis in honey bee colonies.

The hypothesis that parasites and pathogens select for polyandry in eusocial Hymenoptera was tested, using the honey bee Apis mellifera and its microsporidian parasite Nosema apis. Five honey bee colonies with low and five with high worker genetic diversity were infected with N. apis spores. At 54-56 days after inoculation, parasite spores in the workers' midguts were counted to determine whether there was a greater variation of infection intensity (spore counts per worker) in high-diversity colonies than in low-diversity ones. In all colonies there were two discrete sets of workers, with few or many parasite spores. To compare the variations of infection intensity between two colony groups, coefficients of variation were calculated for all workers examined, and for the slightly infected and strongly infected workers. The percentages of slightly infected workers in the low- and high-diversity groups were also compared. None of the comparisons between low- and high-diversity colonies showed significant differences, therefore no relation was found between honey bee workers' genetic diversity and their infection with N. apis.     

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...     

Influence of carbon dioxide on Nosema apis infection of honeybees (Apis mellifera)

Young workers of the honeybee Apis mellifera carnica were individually inoculated with Nosema apis spores subjected to carbon dioxide (CO(2)) treatment. The spores were kept in a CO(2) atmosphere for 30, 35 and 40 h. The course of the infection was evaluated on the basis of the survival rate of bee workers and the number of N. apis spores in their digestive tracts. CO(2) treatment of N. apis spores resulted in faster proliferation of the parasite as well as higher mortality among workers infected with spores kept in CO(2) for 30 and 35 h.     

微孢子虫和狄斯瓦螨分别侵染后的意蜂血淋巴蛋白质含量变化

微孢子虫Nosema apis和狄斯瓦螨微孢子虫Nosema apis和狄斯瓦螨 Varroa destructor (Acari: Varroidae)均为危害意蜂Apis mellifera的重要寄生虫,该文对其危害后意蜂血淋巴蛋白质含量的变化进行了研究。用考马斯亮蓝法测定了意蜂受侵染后血淋巴的蛋白质总量,并用高压超薄层等电点聚焦法进行血淋巴蛋白质分类。结果显示,病蜂血淋巴蛋白质总量,在人工感染微孢子虫后1～10天呈微孢子虫Nosema apis和狄斯瓦螨 Varroa destructor (Acari: Varroidae)均为危害意蜂Apis mellifera的重要寄生虫,该文对其危害后意蜂血淋巴蛋白质含量的变化进行了研究。用考马斯亮蓝法测定了意蜂受侵染后血淋巴的蛋白质总量,并用高压超薄层等电点聚焦法进行血淋巴蛋白质分类。结果显示,病蜂血淋巴蛋白质总量,在人工感染微孢子虫后1～10天呈上升趋势,然后逐渐下降,感染后12～27天保持在感染前意蜂血淋巴总蛋白质含量水平以下。螨侵染后意蜂血淋巴蛋白质含量明显增高,与健康意蜂相比差异极显著。高压超薄层等电点聚焦分析表明：狄斯瓦螨自然侵染意蜂后,意蜂血淋巴蛋白质组分与健康对照组相比发生了明显改变。这些结果提示,意蜂对于微孢子虫或狄斯瓦螨的侵染产生了一定的免疫反应。     

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.     

The incidence of virus diseases in the honey bee

Chronic bee-paralysis virus and sacbrood virus occur commonly in apparently normal honey-bee colonies in Britain. Most sick adult bees not affected by Nosema apis, Malpighamoeba mellificae or Acarapis woodi have chronic paralysis and most dead larvae not affected by micro-organisms have sacbrood. Both virus diseases are probably limited by hereditary factors, but unknown environmental factors also seem to influence disease. Paralysed bees from Australia, Canada, Eire, Germany and Mexico were found to be infected with chronic paralysis virus.     

Ultrastructural changes in the secretion granules of the hypopharyngeal glands of the honeybee infected by Nosema apis and after treatment with fumagillin

Electron-dense secretion granules were numerous in the hypopharyngeal glands of healthy honeybees. In the hyopharyngeal glands of honeybees infected by Nosema apis, these granules appeared to have increased in size and lost their electron density, possessing a core area that consisted of numerous smaller granules, and a slightly electron dense fringe area, which in some cases possessed a crystalline structure. In the hypopharyngeal glands of infected honeybees after treatment with fumagillin, the secretion granules were also large and slightly electron dense, but the granular content was homogenous. Some of these granules were also partially crystallized. These ultrastructural changes in the secretion granules of diseased and fumagillin treated bees, is probably associated with a change in secretory activity of the glands.     

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。     

Outcome of colonization of Apis mellifera by Nosema ceranae

A multiplex PCR-based method, in which two small-subunit rRNA regions are simultaneously amplified in a single reaction, was designed for parallel detection of honeybee microsporidians (Nosema apis and Nosema ceranae). Each of two pairs of primers exclusively amplified the 16S rRNA targeted gene of a specific microsporidian. The multiplex PCR assay was useful for specific detection of the two species of microsporidians related to bee nosemosis, not only in purified spores but also in honeybee homogenates and in naturally infected bees. The multiplex PCR assay was also able to detect coinfections by the two species. Screening of bee samples from Spain, Switzerland, France, and Germany using the PCR technique revealed a greater presence of N. ceranae than of N. apis in Europe, although both species are widely distributed. From the year 2000 onward, statistically significant differences have been found in the proportions of Nosema spp. spore-positive samples collected between and within years. In the first period examined (1999 to 2002), the smallest number of samples diagnosed as Nosema positive was found during the summer months, showing clear seasonality in the diagnosis, which is characteristic of N. apis. From 2003 onward a change in the tendency resulted in an increase in Nosema-positive samples in all months until 2005, when a total absence of seasonality was detected. A significant causative association between the presence of N. ceranae and hive depopulation clearly indicates that the colonization of Apis mellifera by N. ceranae is related to bee losses.     

Low natural levels of Nosema ceranae in Apis mellifera queens

Queens are the primary female reproductive individuals in honey bee colonies and, while they are generally free from Nosema ceranae infection, they are nevertheless susceptible. We sought to determine whether queens are naturally infected by N. ceranae, as these infections could be a factor in the rapid spread of this parasite. Queens were analyzed using real-time PCR and included larval queens, newly emerged, and older mated queens. Overall, we found that all tissues we examined were infected with N. ceranae at low levels but no samples were infected with Nosema apis. The infection of the ovaries and spermatheca suggests the possibility of vertical transmission of N. ceranae.     

Effects of time, temperature, and honey on Nosema apis (Microsporidia: Nosematidae), a parasite of the honeybee, Apis mellifera (Hymenoptera: Apidae).

Newly emerged adult bees were fed with Nosema apis spores subjected to various treatments, and their longevity, proportions of bees infected, and spores per bee recorded. Spores lost viability after 1, 3, or 6 months in active manuka or multifloral honey, after 3 days in multifloral honey, and after 21 days in water or sugar syrup at 33 degrees C. Air-dried spores lost viability after 3 or 5 days at 40 degrees, 45 degrees, or 49 degrees C. Increasing numbers of bees became infected with increasing doses of spores, regardless of their subsequent food (active manuka honey, thyme honey, or sugar syrup). Final spore loads were similar among bees receiving the same food, regardless of dose. Bees fed with either honey had lighter infections than those fed with syrup, but this may have been due to reductions in their longevity. Bees fed with manuka honey were significantly shorter lived, whether infected or not.     

Fixation of microsporidian spores for electron microscopy

Fresh and frozen spores of the microsporidia Nosema apis and Nosema bombi were fixed using various fixatives at different times and temperatures. Paraformaldehyde and technical formaldehyde gave results comparable to or better than glutaraldehyde. Increased fixation temperature improved the fixation of spores from terrestrial hosts. Freezing did not destroy the cytology of the spore.     

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．     

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。     

Honeybee viruses in Uruguay

Mortality of honeybees is a serious problem that beekeepers have to face periodically in Uruguay and worldwide. The presence of RNA viruses, in addition to other pathogens may be one of its possible causes. In this work, we detected Chronic bee paralysis virus, Acute bee paralysis virus, Black queen cell virus, Sacbrood virus and Deformed wing virus in samples of Uruguayan honeybees with or without Varroa destructor and Nosema apis. The detection of viruses in different provinces, simultaneous co-infection of colonies by several viruses and the fact that 96% of the samples were infected with one or more virus, indicates they are widely spread in the region.     

Association of viruses with two protozoal pathogens of the honey bee

Undisturbed honey bee colonies near Rothamsted were commonly infected with a filamentous DNA virus (FV) which was usually associated with Nosema apis in infected adult individuals and occurred most frequently about June. No symptoms were caused by FV, which appeared less harmful than either black queen-ceil virus (BQCV) or bee virus Y (BVY), two isometric RNA viruses also associated with N. apis. Bee virus X, another isometric RNA virus distantly related to BVY, was not associated with N. apis, but prevailed in winter and was then associated significantly with Malpighamoeba mellificae in dead individuals, although it frequently multiplied alone. Results of laboratory experiments supported conclusions made from the field observations about these relationships and their pathology.     

The role of pollen in chalkbrood disease in Apis mellifera: transmission and predisposing conditions

Chalkbrood in honeybees (Apis mellifera L. Himenoptera: Apidae) is a fungal disease caused by Ascosphaera apis (Maassen ex Claussen) Olive and Spiltoir. This disease requires the presence of fungal spores and a predisposing condition in the susceptible brood for the disease to develop. In this study we examined the role of pollen in the development of chalkbrood disease under two experimental conditions: (i) pollen combs were transferred from infected to uninfected beehives and (ii) colonies were deprived of adequate pollen supplies to feed the brood. The results of both treatments confirmed that pollen is an element that should be taken into account when controlling this honeybee disease.     

基于PacBio测序数据的蜜蜂球囊菌转录因子、融合基因及RNA编辑事件的鉴定

【目的】本研究旨在利用已获得的PacBio单分子实时(single molecule real-time, SMRT)测序数据对蜜蜂球囊菌Ascosphaera apis菌丝(AaM)和孢子(AaS)中的转录因子(TF)、融合基因和RNA编辑事件进行鉴定和分析,以期丰富蜜蜂球囊菌的相关信息,并为进一步探究它们的功能提供理论依据。【方法】利用BLASTx工具将AaM和AaS的全长转录本序列比对到Nr, Swiss-Prot和KEGG数据库以获得一致性最高的蛋白序列,再利用hmmscan软件将上述蛋白序列比对到Plant TFdb数据库以获得TF的分类及注释信息。采用TOFU软件中的fusion_finder.py程序进行融合基因的预测,进而分析融合基因的序列和位置信息。使用SAMtools预测AaM和AaS中的RNA编辑事件,再利用ANNOVAR软件对RNA编辑事件进行注释,进而采用相关生物信息学软件对RNA编辑位点基因进行GO功能和KEGG通路注释。【结果】在AaS中共鉴定到17个TF家族的213个TF,其中C2H2家族包含的TF成员最多。在AaM和AaS中分别鉴定到921和510个融合基因,二者共有的融合基因为510个,特有的融合基因分别为411和0个。在AaM和AaS中分别鉴定到547和191次RNA编辑事件,其中AaM中同义单核苷酸突变的数量最多,AaS中非同义单核苷酸突变的数量最多。此外,在AaM中鉴定到12种碱基替换类型,其中发生C->T的RNA编辑事件数量最多,达到158次;在AaS中鉴定到9种碱基替换类型,其中发生C->T和G->T的RNA编辑事件数量最多,均有42次。AaM和AaS中RNA编辑位点基因分别涉及19和24个GO功能条目;此外还能注释到11和20条KEGG通路。【结论】蜜蜂球囊菌的菌丝和孢子中含有丰富的TF、融合基因和RNA编辑位点;转录因子C2H2家族与蜜蜂球囊菌菌丝和孢子的生长发育和细胞活动具有潜在关联;RNA编辑事件的碱基替换类型在蜜蜂球囊菌和其他物种中具有物种特异性;RNA编辑可能在蜜蜂球囊菌菌丝和孢子的生长和代谢中发挥作用。