蜜蜂抗狄斯瓦螨机制的研究进展

狄斯瓦螨Varroa destructor已蔓延至世界各地,给养蜂生产带来巨大挑战,被认为是世界养蜂业的主要威胁。因此,抗螨机制的研究和抗螨蜂种的培育显得尤为重要,而掌握蜜蜂的抗螨机制则是成功培育抗螨蜂种的前提条件。本文从行为、生理及分子机制等多个不同角度对国内外蜜蜂抗狄斯瓦螨机制研究的最新进展进行了详细的阐述。尤其是从分子水平研究蜜蜂的抗螨机制对选育抗螨蜂种具有重要意义,将为利用分子遗传辅助标记筛选方法和先进的生物工程技术并结合传统的育种手段成功培育出具有抗螨性能的优良蜜蜂品系奠定基础。     

狄斯瓦螨对杀螨剂抗性机制的研究进展

狄斯瓦螨Varroa destructor是严重危害西方蜜蜂Apis mellifera的主要寄生螨之一,由于杀螨剂长期大量、单一和连续使用,狄斯瓦螨对杀螨剂的抗性发展日趋严重,探明狄斯瓦螨抗性机制对于治理狄斯瓦螨具有重要意义。狄斯瓦螨抗性形成受遗传因素、人为操作因素及其他生态因素的影响,其抗性机制与化学杀螨剂的种类有关,目前研究较多的是靶标不敏感性机制和解毒代谢增强机制,对拟除虫菊酯类杀螨剂抗性机制研究较为透彻,而对有机磷类和甲咪类杀螨剂抗性机制研究有限。本文基于文献,阐述了狄斯瓦螨对拟除虫菊酯类、有机磷类和甲咪类杀螨剂抗性机制的最新研究进展,讨论了抗性治理的最新研究成果及该领域未来的研究方向,以期为狄斯瓦螨有效治理、杀螨剂的安全有效使用及新型杀螨剂开发等研究提供参考。     

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。     

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。     

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...     

狄斯瓦螨和蜜蜂残翅病毒对蜜蜂健康的协同影响

世界各地大范围的西方蜜蜂Apis mellifera蜂群损失现象已引起科学界和公众的持续关注。狄斯瓦螨Varroa destructor和蜜蜂残翅病毒(Deformed wing virus,DWV)是西方蜜蜂群中最主要的两大生物威胁。尽管二者侵害蜜蜂均已有较长历史,但直至近十年来的研究才发现两者间的协同效应对蜂群健康的影响远超过其单独作用时所造成的危害:(1)蜜蜂残翅病毒可在狄斯瓦螨体内大量复制,继而进一步传播;(2)狄斯瓦螨的刺吸行为使病毒粒子跨越寄主的生理屏障而直接进入蜜蜂血淋巴;(3)狄斯瓦螨的寄生促使蜜蜂残翅病毒的高毒力毒株在蜂群中优势扩增和盛行;(4)狄斯瓦螨影响蜜蜂个体发育与免疫系统等生理机能,以致降低了蜂群对病毒的抵抗力;(5)蜜蜂残翅病毒对宿主造成的免疫抑制有利于狄斯瓦螨的寄生与繁殖。狄斯瓦螨、蜜蜂残翅病毒和西方蜜蜂间的关系已经成为昆虫外寄生物、病原体与寄主相互作用研究的一个典型模型。本文对近十年该领域的相关研究进行综述,以期为蜂群损失的原因调查以及昆虫寄生虫、病原微生物与寄主间关系的研究提供参考和借鉴。     

狄斯瓦螨对意大利蜜蜂工蜂呼吸代谢的影响

【目的】意大利蜜蜂Apis mellifera ligustica(简称"意蜂")是世界重要的授粉昆虫,对维持生态平衡、提高农产品产量和保障粮食安全至关重要。但受狄斯瓦螨Varroa destructor侵害,全世界的意蜂蜂群每年都受到巨大损失。本研究主要探讨狄斯瓦螨对意蜂工蜂呼吸代谢的影响,为今后深入研究狄斯瓦螨与意蜂之间的相互作用奠定基础。【方法】应用SSI多通道昆虫呼吸仪测定感染狄斯瓦螨意蜂与健康意蜂不同发育阶段(4日龄幼虫、5日龄蛹、新出房成蜂和6日龄成蜂)工蜂的耗氧量、CO₂释放量和呼吸商,并分析其变化特征;同时采用实时荧光定量PCR(RT-qPCR)方法分析狄斯瓦螨感染意蜂与健康意蜂成年工蜂中呼吸代谢相关基因(Coq7,COXⅠ,CytB,CytC和IF-2mt)的表达量变化。【结果】受狄斯瓦螨侵染后,意蜂工蜂耗氧量、CO₂释放量呈现出先上升后下降的趋势,其中耗氧量从5日龄蛹期的0.0244 mL/min下降至6日龄成蜂期的0.0093 mL/min; CO₂释放量从5日龄蛹期的0.0174 mL/min下降...     

不同组配的蜜蜂信息素对西方蜜蜂的蜂蜜生产及繁殖性能影响

为了探究不同组配的蜜蜂信息素对西方蜜蜂Apis mellifera蜂蜜生产及繁殖性能的影响。本研究在不同浓度（0.05 μg/μL、0.10 μg/μL和0.15 μg/μL）反式-9-氧代-2-癸烯酸\[(E)-9-oxodec-2-enoicacid,9-ODA\]对工蜂卵黄原蛋白基因（Vg）表达影响基础上,以蜂蜡为载体,用4种蜂王上颚腺信息素（9-ODA,9-HDA,HOB,HVA）与蜜蜂幼虫饥饿信息素（β-罗勒烯）按照一定比例组配了4种蜜蜂信息素挂片（T1-1、T1-2、T2-1、T2-2）,同时以纯蜂蜡挂片作为空白对照组（CK）。系统研究了4种蜜蜂信息素挂片对西方蜜蜂无王群急造王台以及有王群的蜂蜜产量、封盖子数和群势影响。结果表明：人工饲喂0.05 μg/μL、0.10 μg/μL和0.15 μg/μL的9-ODA,对工蜂Vg表达水平具有显著抑制作用（P<0.05）;与对照组相比,4个实验组（T1-1、T1-2、T2-1和T2-2组）出现封盖王台的时间均有显著延迟（P<0.05）,推迟时间2~3 d;T2-1组蜂蜜产量显著高于对照组（P<0.05）,蜂蜜产量提高24.00%;T1-2组、T2-1组和T2-2组封盖子数量都显著高于对照组（P<0.05）,分别提高84.52%、64.50%和80.09%;T1-2组和T2-1组蜂群群势显著高于对照组（P<0.05）,分别提高了53.37%和50.85%。因此不同组配的蜜蜂信息素对西方蜜蜂蜂蜜生产及繁殖性能都起到了积极作用,相关研究结果对养蜂生产中合理利用蜜蜂信息素有指导意义。     

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)。     

The effect of the ectoparasitic mite, Varroa destructor on adult worker honeybee (Apis mellifera) emergence weights, water, protein, carbohydrate, and lipid levels

Wet weight, dry weight and water contents of emerging honeybees (Apis mellifera L. [Hymenoptera: Apidae]) infested with the ectoparasitic mite Varroa destructor (Anderson) (Acari: Varroidae) were all negatively correlated with increasing numbers of mites. It was estimated that for every female mite present during the bees' development, the host would lose three percent of its body water. Parasitised bees also emerged with lower head and abdomen concentrations of protein and with lower abdominal carbohydrate concentrations. Lipid concentrations were not detectably affected by V. destructor infestation. The losses of metabolic reserves were not, however, judged to be serious enough to be directly responsible for the high bee mortality and ultimate colony collapse that are associated with the arrival of Varroa in a hive. Some 8.5% of the emerging bees exhibited morphological deformities and deformity was positively correlated with increasing numbers of mites in brood cells. Deformed bees were, however, found in all categories of parasitosis, suggesting that other factors, such as infectious agents, may be involved. Mites that fed on either live or dead U¹⁴C- labelled bees acquired the label within 24 h and it was calculated that an adult female mite consumes 0.67 l haemolymph 24 h^–1. It was also demonstrated that ¹⁴C was transmitted to a previously non-radio-labelled bee when a mite that had been feeding on a labelled bee changed hosts. The level of transfer was above that which could have arisen through contamination of the mites' mouthparts and supports the suggestion that Varroa is an important vector of pathogens such as viruses.     

Varroa management in small bites

Chelifers (Arachnida: Pseudoscorpionida), also known as pseudoscorpions, have been reported to be beneficial honeybee hive generalist pest predators for over 100 years and are occasionally noted by beekeepers in their hives. We collected chelifers within or closely associated with beehives in New Zealand. Under video observation conditions, they predated upon varroa mites while studiously ignoring bee larvae. Varroa mites reproduce at exponential rates during the spring season, and current chemical miticides rely on single treatments aiming for at least 90% control. An alternate strategy, removal of mites at a rate matching their reproductive capacity, although mathematically obvious, fails unless a suitable biological control agent is available. Our observations build on over 100 years of sporadic work to provide further evidence that chelifers show clear potential to be a suitable predator for varroa management in beehives. Approximately 25 chelifers can be expected to manage varroa populations in a single hive.     

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.     

Muscle potentials and temperature acclimation and acclimatization in flight muscles of workers and drones of Apis mellifera

1. 1.Muscle potentials in fibrillar flight muscles of worker and drone honeybees were recorded extracellularly at thoracic temperatures from 30 to 10°C.

2. 2.Extinction temperatures for muscle potentials were higher in drones for all treatments.

3. 3.Cold acclimation (15°C) lowered extinction temperatures significantly in workers and drones. Acclimitization changed extinction temperatures significantly only in drones.

4. 4.Cold acclimitization had a bigger effect on the rate of muscle potential amplitude decline with decreasing temperature than acclimation.

5. 5.Acclimation and acclimitization had no effect on the increase of muscle potential duration with falling temperature.

6. 6.Muscle potential frequency during shivering was not much different between cold and warm treated bees.

意大利蜜蜂工蜂幼虫nkd基因的生物信息学分析及功能研究

【目的】意大利蜜蜂(Apis mellifera ligustica,简称意蜂)是西方蜜蜂(Apis mellifera)的亚种之一。蜜蜂球囊菌(Ascosphaera apis)侵染意蜂幼虫导致白垩病。本研究对西方蜜蜂裸表皮蛋白(naked cuticle, Nkd)进行保守基序预测和系统进化分析,并通过RNAi明确nkd基因对意蜂工蜂幼虫体重及宿主响应蜜蜂球囊菌胁迫的免疫应答的影响,以期丰富西方蜜蜂基因nkd的信息,并揭示意蜂幼虫nkd的功能。【方法】通过MEME软件预测西方蜜蜂和其他9个物种Nkd蛋白的保守基序。采用MEGA X软件对西方蜜蜂及其他9个物种的Nkd蛋白进行系统进化分析。通过饲喂dsRNA对意蜂幼虫肠道内的nkd进行RNAi。使用电子天平对幼虫进行称重。利用RT-qPCR检测nkd基因的干扰效率及免疫基因的相对表达量。【结果】西方蜜蜂与东方蜜蜂、柑橘凤蝶、家蚕和金凤蝶的Nkd蛋白均含有3个保守基序(motif 1、motif 2 和motif 3),说明上述5个昆虫物种的Nkd具有较高的保守性。西方蜜蜂与东方蜜蜂的Nkd蛋白聚为一支,说明二者的亲缘关系近。与dsRNA-egfp组相比,dsRNA-nkd组5日龄和6日龄幼虫肠道内nkd的表达量均极显著下调(P<0.001),干扰效率分别为49.60%和56.40%。另外,dsRNA-nkd组幼虫体重较dsRNA-egfp组显著下降,说明nkd显著影响幼虫体重。RT-qPCR结果显示,4日龄幼虫肠道内abaecin、apidaecin、birc5、defensin-1和PGRP-S2均被激活表达;5日龄幼虫肠道内abaecin、apidaecin、birc5和defensin-1均被激活表达,PGRP-S2的表达受到抑制;6日龄幼虫肠道内abaecin被激活表达,而apidaecin、birc5、defensin-1和PGRP-S2的表达均受到抑制,说明上述5个免疫基因在宿主响应胁迫的过程中呈不同的表达趋势,均参与宿主的免疫应答,nkd与abaecin和apidaecin的表达存在负向调控关系。【结论】西方蜜蜂的Nkd蛋白含有3个保守基序(motif 1、motif 2和motif 3),西方蜜蜂与东方蜜蜂的Nkd蛋白亲缘关系最近,通过饲喂dsRNA能有效干扰意蜂工蜂幼虫肠道内nkd表达,nkd影响意蜂工蜂幼虫体重及宿主对蜜蜂球囊菌胁迫的免疫应答。     

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。     

Development of a user-friendly delivery method for the fungus Metarhiziumanisopliae to control the ectoparasitic mite Varroa destructor in honey bee, Apis mellifera, colonies

A user-friendly method to deliver Metarhizium spores to honey bee colonies for control of Varroa mites was developed and tested. Patty blend formulations protected the fungal spores at brood nest temperatures and served as an improved delivery system of the fungus to bee hives. Field trials conducted in 2006 in Texas using freshly harvested spores indicated that patty blend formulations of 10 g of conidia per hive (applied twice) significantly reduced the numbers of mites per adult bee, mites in sealed brood cells, and residual mites at the end of the 47-day experimental period. Colony development in terms of adult bee populations and brood production also improved. Field trials conducted in 2007 in Florida using less virulent spores produced mixed results. Patty blends of 10 g of conidia per hive (applied twice) were less successful in significantly reducing the number of mites per adult bee. However, hive survivorship and colony strength were improved, and the numbers of residual mites were significantly reduced at the end of the 42-day experimental period. The overall results from 2003 to 2008 field trials indicated that it was critical to have fungal spores with good germination, pathogenicity and virulence. We determined that fungal spores (1 × 10¹⁰ viable spores per gram) with 98% germination and high pathogenicity (95% mite mortality at day 7) provided successful control of mite populations in established honey bee colonies at 10 g of conidia per hive (applied twice). Overall, microbial control of Varroa mite with M. anisopliae is feasible and could be a useful component of an integrated pest management program.