蜜蜂瓦螨敏感卫生行为研究进展

蜜蜂具有很高的生态价值和经济价值,对农业生产帮助巨大。然而,狄斯瓦螨Varroa destructor寄生给西方蜜蜂Apis mellifera蜂群造成重大损失,对蜜蜂健康构成严重威胁,因此,狄斯瓦螨的防治变得尤为紧要。虽然化学防治是防治狄斯瓦螨常用且有效措施,但仍存在许多缺点,如造成蜂产品污染、导致蜂螨产生抗药性等。另一方面,培育抗螨蜂种被证明是可持续的狄斯瓦螨防治方法。瓦螨敏感卫生行为(Varroa sensitive hygiene, VSH)是蜜蜂重要的抗螨性状之一。本文从狄斯瓦螨的生活周期、对蜜蜂的危害、蜜蜂抗螨行为、瓦螨敏感卫生行为调控和遗传育种等方面进行综述,为狄斯瓦螨防治和抗螨蜂种选育提供参考。     

大蜂螨对一些气味物质的趋性

狄斯瓦螨Varroa destructor Anderson & Trueman是意大利蜜蜂Apis mellifera Spinola的主要外寄生螨。雌成螨在幼虫巢房封盖前不久侵入幼虫巢房,并开始繁殖为害。从雌成螨在一个很短的时间内进入蜜蜂幼虫巢房,以及雄蜂幼虫巢房蜂螨的寄生率明显高于工蜂幼虫巢房的现象,表明蜜蜂幼虫体表一些信息素(semiochemicals)可能起着重要的引诱作用。作者对与大蜂螨相关的19种气味物质进行筛选,并对封盖前工蜂幼虫和雄蜂幼虫表皮挥发物进行气谱及气-质联谱测定。结果表明:雄蜂6龄幼虫对大蜂螨的引诱作用显著高于丁香水等10种气味物质。工蜂和雄蜂末龄幼虫体表挥发物的共有组份是9-二十三烯(C23H46),但它在雄蜂幼虫中所占的比例要明显高于工蜂幼虫。工蜂幼虫的特有主要组分是十八烷(C18H38)和9-甲基十九烷(C19H40);而雄蜂幼虫的特有主要组分是二十五烷(C25H52)和二十三烷(C23H48)。     

Non-reproduction in the honeybee mite Varroa jacobsoni

This study brings together the results of investigations into both the causes and subsequent consequences of mites which fail to produce viable female offspring. These showed that the premature death of the male offspring within the host cell leads to unfertilized adult female offspring emerging from the cell. These unfertilized mites cannot mate and so never produce viable offspring, although they do enter cells and attempt to reproduce. Therefore, virgin females cannot account for females which normally only produce male offspring, suggesting that these males are not produced parthenogenically. In the majority of mites, the type of reproductive behaviour does not change, i.e. once abnormal always abnormal. The possible role of premature male mite death in the resistance of (Africanized) bees is discussed.     

狄斯瓦螨与蜜蜂的寄生关系

蜜蜂Apis spp.是重要的经济昆虫,也是研究最为深入和广泛的社会性昆虫。狄斯瓦螨Varroa destructor是蜜蜂的体外寄生虫,是对西方蜜蜂Apis mellifera蜂群健康危害最为严重的生物因子。近十多年来,由于全球蜂群损失现象严重,而同时以蜜蜂为代表的授粉昆虫的健康直接关系到农业生产和生态安全,关于狄斯瓦螨与蜜蜂的寄生关系的研究受到极大关注。作为社会性昆虫的一种体外寄生虫,狄斯瓦螨不仅需要适应蜜蜂个体的生长发育,借助蜜蜂化蛹期间的封盖期完成繁殖,同时还要能够逃避蜜蜂社会性行为的清理。本文从狄斯瓦螨的生物学特性以及其与寄主间的互作关系等方面进行论述,以期进一步理解寄生虫-无脊椎动物寄主(特别是社会性昆虫寄主)的相互作用,为寄生虫病学研究提供借鉴。     

蜜蜂寄生螨—狄斯瓦螨的研究进展

狄斯瓦螨Varroa destructor是对世界养蜂业危害最大的蜜蜂寄生虫,严重危害蜜蜂封盖幼虫、蛹和成蜂,并携带和传播蜜蜂病毒,造成蜂群生产力严重下降乃至全群毁灭。狄斯瓦螨的有效防治措施的研发有赖于对其研究进展的了解,本文综述了以下3方面的研究概况:1)狄斯瓦螨的繁殖特性;2)对蜜蜂的危害;3)主要防治方法。以期为蜂螨相关的研究和应用奠定基础。     

蜜蜂巢房大小影响狄斯瓦螨的繁殖行为

在具有相同类型幼虫的雄蜂和工蜂巢房中,人工接入狄斯瓦螨Varroa destructorAnderson&Trueman,比较巢房大小不同,对于螨繁殖的影响。结果显示:狄斯瓦螨在具有工蜂幼虫的工蜂房(WW)中的繁殖率为94.4%,而在具有工蜂幼虫的雄蜂房(WD)中繁殖率只有27.7%,差异极显著。在具有工蜂幼虫的工蜂房中,每只雌螨产出后代的平均数为3.35±1.56只;在具有工蜂幼虫的雄蜂房中每只雌螨产出后代的平均数为0.49±0.93只,差异极显著。表明:在具有相同类型幼虫存在的情况下,狄斯瓦螨喜欢较小的巢房,狄斯瓦螨在较小巢房中的繁殖能力明显高于较大的巢房。     

钠离子通道与蜜蜂狄斯瓦螨对氟胺氰菊酯的抗性机理

狄斯瓦螨Varroadestructor是全世界蜜蜂最严重的寄生虫 ,目前 ,它对主要防治药物———拟除虫菊酯类的氟胺氰菊酯已产生明显抗性 ,严重影响其防治效果。近年来神经生理学研究结果证实 :电压门控的钠离子通道是拟除虫菊酯作用的位点。钠通道结构的改变 ,是拟除虫菊酯类杀虫剂毒理的主要基础 ,也是产生抗药性的基础。该文介绍了近年来国内外研究电压门控钠离子通道、拟除虫菊酯对钠通道的作用、钠通道与拟除虫菊酯的抗性和狄斯瓦螨对氟胺氰菊酯抗性机理研究的新进展     

A Causal Analysis of Observed Declines in Managed Honey Bees (Apis mellifera)

The European honey bee (Apis mellifera) is a highly valuable, semi-free-ranging managed agricultural species. While the number of managed hives has been increasing, declines in overwinter survival, and the onset of colony collapse disorder in 2006, precipitated a large amount of research on bees’ health in an effort to isolate the causative factors. A workshop was convened during which bee experts were introduced to a formal causal analysis approach to compare 39 candidate causes against specified criteria to evaluate their relationship to the reduced overwinter survivability observed since 2006 of commercial bees used in the California almond industry. Candidate causes were categorized as probable, possible, or unlikely; several candidate causes were categorized as indeterminate due to lack of information. Due to time limitations, a full causal analysis was not completed at the workshop. In this article, examples are provided to illustrate the process and provide preliminary findings, using three candidate causes. Varroa mites plus viruses were judged to be a “probable cause” of the reduced survival, while nutrient deficiency was judged to be a “possible cause.” Neonicotinoid pesticides were judged to be “unlikely” as the sole cause of this reduced survival, although they could possibly be a contributing factor.     

Development of a 44K SNP assay focussing on the analysis of a varroa-specific defence behaviour in honey bees (Apis mellifera carnica)

Honey bees are exposed to a number of damaging pathogens and parasites. The most destructive among them, affecting mainly the brood, is Varroa destructor. A promising approach to prevent its spread is to breed for Varroa-tolerant honey bees. A trait that has been shown to provide significant resistance against the Varroa mite is hygienic behaviour, a behavioural response of honey bee workers to brood diseases in general. This study reports the development of a 44K SNP assay, specifically designed for the analysis of hygienic behaviour of individual worker bees (Apis mellifera carnica) directed against V. destructor. Initially, 70,000 SNPs chosen from a large set of SNPs published by the Honey Bee Genome Project were validated for their suitability in the analysis of the Varroa resistance trait 'uncapping of Varroa-infested brood'. This was achieved by genotyping of pooled DNA samples of trait bearers and two trait-negative controls using next-generation sequencing. Approximately 36,000 of these validated SNPs and another 8000 SNPs not validated in this study were selected for the construction of a SNP assay. This assay will be employed in following experiments to analyse individualized DNA samples in order to identify quantitative trait loci (QTL) involved in the control of the investigated trait and to evaluate and possibly confirm QTL found in other studies. However, this assay is not just suitable to study Varroa tolerance, it is as well applicable to analyse any other trait in honey bees. In addition, because of its high density, this assay provides access into genomic selection with respect to several traits considered in honey bee breeding. It will become publicly available via AROS Applied Biotechnology AS, Aarhus, Denmark, before the end of the year 2011.     

Behavioural responses of Varroa destructor (Acari: Varroidae) to extracts of larvae, cocoons and brood food of worker and drone honey bees, Apis mellifera (Hymenoptera: Apidae)

Abstract. Varroa destructor is a parasitic mite of the honey bee species Apis cerana Fabr . and A. mellifera L. Mature females reproduce on the immature stages of their hosts, producing more viable female offspring on drone hosts than on worker hosts. Thus, immature drones are more likely to be infested with mites than immature workers. To investigate the hypothesis that differences in host chemistries underlie the biased distribution of mites between worker and drone brood, the arrestment responses of mites to solvent extracts of a number of stimuli normally encountered by a mite during its life cycle were measured. Mites were arrested by cuticular extracts of worker and drone larvae obtained at 0, 24 and 48 h prior to the time when cell capping is completed. Mites were also arrested by extracts of worker and drone, brood food and cocoons, and by a blend of synthetic fatty acid esters previously shown to be active in the host acquisition process. In a wind tunnel bioassay, mites were attracted to odours from living fifth-instar worker and drone larvae, but not to volatiles from cocoons, brood food or a blend of fatty acid esters. The sex of the host was not an important factor affecting the behavioural responses of the mites in any assay. We conclude that host kairomones play a role in the host acquisition process, but we found no evidence to support the hypothesis that mites use these substances to differentiate between worker and drone brood.     

雅氏瓦螨对氟胺氰菊酯的抗性机理初探

用有效成分为1000μg/L的氟胺氰菊酯药液对雅氏瓦螨Varroa jacobsoniOudemans敏感个体的腹部表皮进行穿透性测定,结果表明药液无法通过表皮起毒杀作用。通过添加酶抑制剂多功能氧化酶(PBO)和酯酶(DEF)的增效测定,结果显示PBO在抗性和敏感螨中分别增加毒效为3.27和1.80倍;而DEF为3.23和1.67倍。反映在抗性蜂螨的抗药性与多功能氧化酶的活性有密切相关,也与酯酶活性有关。对抗性螨和敏感螨的羧酸酯酶的活力测定,显示出在抗性螨中酶活指数高140%以上。同时对酯酶电泳进行扫描,也发现抗性螨与敏感螨的峰值存在差异。     

Tyramine functions as a toxin in honey bee larvae during Varroa-transmitted infection by Melissococcus pluton

From wounds of honey bee pupae, caused by the mite Varroa destructor, coccoid bacteria were isolated and identified as Melissococcus pluton. The bacterial isolate was grown anaerobically in sorbitol medium to produce a toxic compound that was purified on XAD columns, gelfiltration and preparative HPLC. The toxic agent was identified by GC-MS and FTICR-MS as tyramine. The toxicity of the isolated tyramine was tested by a novel mobility test using the protozoon Stylonychia lemnae. A concentration of 0.2 mg/ml led to immediate inhibition of mobility. In addition the toxicity was studied on honey bee larvae by feeding tyramine/water mixtures added to the larval jelly. The lethal dosis of tyramine on 4-5 days old bee larvae was determined as 0.3 mg/larvae when added as a volume of 20 microl to the larval food in brood cells. Several other biogenic amines, such as phenylethylamine, histamine, spermine, cadaverine, putrescine and trimethylamine, were tested as their hydrochloric salts for comparison and were found to be inhibitory in the Stylonychia mobility test at similar concentrations. A quantitative hemolysis test with human red blood cells revealed that tyramine and histamine showed the highest membranolytic activity, followed by the phenylethylamine, trimethylamine and spermine, while the linear diamines, cadaverine and putrescine, showed a significantly lower hemolysis when calculated on a molar amine basis. The results indicate that tyramine which is a characteristic amine produced by M. pluton in culture, is the causative agent of the observed toxic symptoms in bee larvae. Thus this disease, known as European foulbrood, is possibly an infection transmitted by the Varroa destructor mite.     

中草药精油对蜜蜂狄斯瓦螨的熏杀效果

在实验室条件下测定10种中草药精油对蜜蜂狄斯瓦螨Varroa destructor Anderson&Trueman的熏蒸效果,通过测定中草药精油对蜜蜂和螨的毒性,筛选出具有杀螨活性而对蜜蜂较安全的中草药精油。结果表明:中草药精油对蜜蜂都有一定的毒害;而在对蜜蜂无毒性的剂量下,48h时茴香油、丁香油、肉桂油分别能引起92.5%、54%和12%的螨死亡,显著高于对照组(P<0.05);根据初步筛选结果,选择茴香油和丁香油进行进一步毒力测定,结果表明48h时茴香油对螨的LD50为0.949μL,蜜蜂的LD50为4.033μL;丁香油对螨的LD50为0.795μL,蜜蜂的LD50为1.965μL。茴香油在48h时有着较高的选择比(蜜蜂的LD50/螨的LD50=4.250);GC-MS鉴定茴香油最主要成分是茴香脑(占总成分的88.72%),丁香油的主要成分是丁香酚(68.28%)和石竹烯(20.79%)。可见,茴香油和丁香油在控制狄斯瓦螨的应用上具有很大潜力。     

信息素介导的西方蜜蜂与狄斯瓦螨互作研究进展

狄斯瓦螨是一种严重危害西方蜜蜂的体外寄生螨,是世界养蜂业的最大威胁.人们广泛采用化学方法防治狄斯瓦螨,但易引起狄斯瓦螨的抗药性、蜜蜂中毒和蜂产品药物残留等问题.为此,人们尝试了多种蜂螨绿色防控技术.其中利用蜜蜂信息素防治狄斯瓦螨是一个重要的研究方向.研究表明,狄斯瓦螨能利用蜜蜂信息素识别处于不同发育阶段的寄主,并对特定时期的寄主表现出高度的选择性.近年来,多种能作用于狄斯瓦螨的蜜蜂信息素相继被报道.这些信息素包括成蜂、蛹和幼虫信息素.有的信息素对狄斯瓦螨表现出驱避作用,有的则表现出引诱作用.本文对这些信息素的种类、主要组成成分、对狄斯瓦螨的作用等进行了综述,旨在为今后的研究与应用提供参考.     

香精油的抗蜂螨作用及其在蜂群中的应用

香精油及其组分具有显著的抗螨效果。研究者通过筛选试验测定了多种香精油及其组分的抗螨能力,多数在实验室中表现出良好的抗螨效果,但除了百里酚及其混合物外,很少在野外试验中表现出强抗螨能力。百里酚及其混合物的抑螨率超过了90%,对蜜蜂危害较小,长期使用后残留量很低。很有必要对香精油的抗蜂螨作用作进一步的研究,同时结合其它防治手段,建立一套全面的害虫防治策略,以控制蜂螨的危害。     

Reproduction of ectoparasitic mites in a coevolved system: Varroa spp.—Eastern honey bees,Apis cerana

Parasite host shifts can impose a high selective pressure on novel hosts. Even though the coevolved systems can reveal fundamental aspects of host–parasite interactions, research often focuses on the new host–parasite relationships. This holds true for two ectoparasitic mite species, Varroa destructor and Varroa jacobsonii, which have shifted hosts from Eastern honey bees, Apis cerana, to Western honey bees, Apis mellifera, generating colony losses of these pollinators globally. Here, we study infestation rates and reproduction of V. destructor and V. jacobsonii haplotypes in 185 A. cerana colonies of six populations in China and Thailand to investigate how coevolution shaped these features. Reproductive success was mostly similar and low, indicating constraints imposed by hosts and/or mite physiology. Infestation rates varied between mite haplotypes, suggesting distinct local co‐evolutionary scenarios. The differences in infestation rates and reproductive output between haplotypes did not correlate with the virulence of the respective host‐shifted lineages suggesting distinct selection scenarios in novel and original host. The occasional worker brood infestation was significantly lower than that of drone brood, except for the V. destructor haplotype (Korea) from which the invasive lineage derived. Whether mites infesting and reproducing in atypical intraspecific hosts (i.e., workers and queens) actually predisposes for and may govern the impact of host shifts on novel hosts should be determined by identifying the underlying mechanisms. In general, the apparent gaps in our knowledge of this coevolved system need to be further addressed to foster the adequate protection of wild and managed honey bees from these mites globally.     

Varroa jacobsoni (Acari: Varroidae) is more than one species

Varroa jacobsoni was first described as a natural ectoparasitic mite of the Eastern honeybee (Apis cerana) throughout Asia. It later switched host to the Western honeybee (A. mellifera) and has now become a serious pest of that bee worldwide. The studies reported here on genotypic, phenotypic and reproductive variation among V. jacobsoni infesting A. cerana throughout Asia demonstrate that V. jacobsoni is a complex of at least two different species. In a new classification V. jacobsoni is here redefined as encompassing nine haplotypes (mites with distinct mtDNA CO-I gene sequences) that infest A. cerana in the Malaysia–Indonesia region. Included is a Java haplotype, specimens of which were used to first describe V. jacobsoni at the beginning of this century. A new name, V. destructor n. sp., is given to six haplotypes that infest A. cerana on mainland Asia. Adult females of V. destructor are significantly larger and less spherical in shape than females of V. jacobsoni and they are also reproductively isolated from females of V. jacobsoni. The taxonomic positions of a further three unique haplotypes that infest A. cerana in the Philippines is uncertain and requires further study.Other studies reported here also show that only two of the 18 different haplotypes concealed within the complex of mites infesting A. cerana have become pests of A. mellifera worldwide. Both belong to V. destructor, and they are not V. jacobsoni. The most common is a Korea haplotype, so-called because it was also found parasitizing A. cerana in South Korea. It was identified on A. mellifera in Europe, the Middle East, Africa, Asia, and the Americas. Less common is a Japan/Thailand haplotype, so-called because it was also found parasitizing A. cerana in Japan and Thailand. It was identified on A. mellifera in Japan, Thailand and the Americas.Our results imply that the findings of past research on V. jacobsoni are applicable mostly to V. destructor. Our results will also influence quarantine protocols for bee mites, and may present new strategies for mite control.     

蜜蜂幼虫血淋巴游离氨基酸和微量元素含量的差异对其抗螨特性的影响

重新界定的外寄生螨类---狄斯瓦螨Varroa destructor(Anderson and Trueman),严重危害全世界的西方蜜蜂Apis mellifera。但是对其原始寄主东方蜜蜂Apis cerana不构成可见的危害。在西方蜜蜂群中,狄斯瓦螨在雄蜂房和工蜂房都能进行繁殖。在其亚洲的原始寄主东方蜜蜂群中,它们可以寄生于雄蜂和工蜂,但在工蜂房中不育。蜜蜂的血淋巴是狄斯瓦螨生存和繁殖需要摄取的惟一食物来源,推测血淋巴中的某种物质含量会影响狄斯瓦螨的繁殖。对中华蜜蜂Apis ceranaFabricius和意大利蜜蜂ApismelliferaL.工蜂和雄蜂封盖幼虫血淋巴中游离氨基酸和与营养有关的微量元素含量进行了比较,发现其存在明显差异,并推测这些差异与东方蜜蜂抗螨能力强有关。     

狄斯瓦螨和蜜蜂病毒对意大利蜜蜂蜂群越冬的影响

越冬期是蜂群损失最主要的阶段.通过比较分析45个意大利蜜蜂Apis mellifera ligustica蜂群在繁殖越冬蜂前的狄斯瓦螨Varroa destructor寄生率和病毒感染情况、越冬表现及越冬期存活蜂群的病毒感染情况等,探究与越冬期蜜蜂健康紧密相关的影响因素.结果表明,繁殖越冬蜂前蜂群的狄斯瓦螨寄生率与蜜蜂残翅病毒(DWV)和以色列急性麻痹病毒(IAPV)基因组拷贝数呈中等线性相关关系(pDWV=0.003,pIAPV=0.001),且狄斯瓦螨寄生率低于9％的蜂群与DWV感染程度相关性更高,而寄生率高于9％的蜂群与IAPV的相关性更高.越冬期死亡蜂群在繁殖越冬蜂前的狄斯瓦螨寄生率和IAPV病毒基因组拷贝数均显著高于存活蜂群.狄斯瓦螨和IAPV是本次实验中意蜂蜂群越冬期健康的首要影响因素.结合狄斯瓦螨寄生率和IAPV基因组拷贝数的正相关性,本研究认为在繁殖越冬蜂前将蜂螨寄生率控制在较低水平(9％以下)能有效减少越冬期意蜂蜂群损失.