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.     

Genes important for survival or reproduction in Varroa destructor identified by RNAi

The Varroa mite,(Varroa destructor),is the worst threat to honey bee health worldwide.To explore the possibility of using RNA interference to control this pest, we determined the effects of knocking down various genes on Varroa mite survival and reproduction.Double-stranded RNA (dsRNA)of six candidate genes (Da,Pros26S,RpL8, RpL11,RpPO and RpS13)were synthesized and each injected into Varroa mites,then mite survival and reproduction were assessed.Injection of dsRNA for Da (Daughterless)and Pros26S (Gene for proteasome 26S subunit adenosine triphosphatase)caused a significant reduction in mite survival,with 3.57%±1.94% and 30.03%±11.43% mites surviving at 72 h post-inj ection (hpi),respectively.Control mites injected with green fluorescent protein (GFP)-dsRNA showed survival rates of 81.95%±5.03% and 82.36 ±2.81%,respectively. Injections of dsRNA for four other genes (RpL8,RpL11,RpPO and RpS13)did not affect survival significantly,enabling us to assess their effect on Varroa mite reproduction.The number of female offspring per mite was significantly reduced for mites injected with dsRNA of each of these four genes compared to their GFP-dsRNA controls.Knockdown of the target genes was verified by real-time polymerase chain reaction for two genes important for reproduction (RpL8,RpL11)and one gene important for survival (Pros26S). In conclusion,through RNA interference,we have discovered two genes important for mite survival and four genes important for mite reproduction.These genes could be explored as possible targets for the control of Varroa destructor in the future.     

Amplification of multiple copies of mitochondrial Cytochrome b gene fragments in the Australian freshwater crayfish,Cherax destructor Clark (Parastacidae: Decapoda)

Non-coding copies of fragments of the mitochondrial genome translocated to the nucleus or pseudogenes are being found with increasing frequency in a diversity of organisms. As part of a study to evaluate the utility of a range of mitochondrial gene regions for population genetic and systematic studies of the Australian freshwater crayfish, Cherax destructor (the yabby), we report the first detection of Cytochrome b (Cyt b) pseudogenes in crustaceans. We amplified and sequenced fragments of the mitochondrial Cyt b gene from 14 individuals of C. destructor using polymerase chain reaction (PCR) with primers designed from conserved regions of Penaeus monodon and Drosophila melanogaster mitochondrial genomes. The phylogenetic tree produced from the amplified fragments using these primers showed a very different topology to the trees obtained from sequences from three other mitochondrial genes, suggesting one or more nuclear pseudogenes have been amplified. Supporting this conclusion, two highly divergent sequences were isolated from each of two single individuals, and a 2 base pair (bp) deletion in one sequence was observed. There was no evidence to support inadvertent amplification of parasite DNA or contamination of samples from other sources. These results add to other recent observations of pseudogenes suggesting the frequent transfer of mitochondrial DNA (mtDNA) genes to the nucleus and reinforces the necessity of great care in interpreting PCR-generated Cyt b sequences used in population or evolutionary studies in freshwater crayfish and crustaceans more generally.     

Resistance of the honey bee, Apis mellifera to the acarian parasite Varroa destructor: behavioural and electroantennographic data

Abstract. One way in which Apis mellifera honey bees resist Varroa destructor is by detection and elimination of nestmates. This study uses behavioural tests and electroanntennography to assess the role of chemostimuli in recognition by honey bees of this acarian ectoparasite. Behavioural tests using living or dead parasites involved observation of honey bee grooming activity (antennation) under controlled conditions in Petri dishes, and removal behaviour (uncapping and elimination of parasitized and unparasitized control brood cells) under natural conditions. Some bees from colonies with both small and large parasite populations showed aggressive behaviour (biting). No difference was observed according to whether the mite was dead or alive. Under natural conditions, bees uncapped more parasitized cells than control cells. Electroantennographic tests were performed to measure sensitivity to various Varroa extracts at three concentrations (10, 20 and 30 Varroa Equivalents). Only 30 Varroa Equivalent methanol extracts made from Varroa collected from brood cells elicited significantly greater antennal response than controls (pure solvent). All three methanol extracts elicited significantly greater antennal response than controls. No response was observed using Varroa extracts made with acetone or hexane. These findings suggest that polar products may act as chemostimuli for recognition of V. destructor by honey bees. Further study will be necessary to determine which polar products are involved in this recognition and assess grooming and removal behaviour using these products.     

马铃薯腐烂茎线虫L 型半胱氨酸蛋白酶新基因(Dd-cpl-1) 的克隆与序列分析

L型半胱氨酸蛋白酶基因 (Cathepsin L-like cysteine proteinase gene) 为与植物寄生线虫寄生能力相关的多功能基因。运用RT-PCR和RACE的方法从马铃薯腐烂茎线虫Ditylenchus destructor中克隆出1个L型半胱氨酸蛋白酶新基因Dd-cpl-1 (GenBank登录号为GQ180107)。该基因Dd-cpl-1 cDNA全长序列含有1个1 131 bp的开放性阅读框 (ORF),编码376个氨基酸残基,其5′末端及3′末端分别含有29 bp和159 bp的非编码区 (UTR)。Dd-cpl-1内含子外显子结构分析结果表明,其基因组序列包含7个内含子,且各内含子两端剪接位点序列遵守GT/AG规则。Dd-cpl-1基因推定的蛋白Dd-CPL-1与松材线虫L型半胱氨酸蛋白酶高度同源,一致性达到77％。以不同物种中L 型半胱氨酸蛋白酶氨基酸序列进行比对分析,推测推定的蛋白 Dd-CPL-1含有L型半胱氨酸蛋白酶基因家族高度保守的催化三联体 (Cys183,His322 和Asn343) 以及ERFNIN基系和GNFD基系。半胱氨酸蛋白酶系统发育分析表明,Dd-cpl-1 属于由L型半胱氨酸蛋白酶组成的进化分支。Dd-cpl-1的这些序列特征进一步表明其为L型半胱氨酸蛋白酶基因。这是首次在马铃薯腐烂茎线虫中克隆到的L型半胱氨酸蛋白酶,为今后在蛋白水平对其进行进一步的功能分析提供基础。     

红车轴草中(6aR,11aR)-三叶豆紫檀苷对马铃薯腐烂茎线虫的麻醉活性研究

从红车轴草(Trifolium pratense L.)根乙醇提取物中分离得到了黄酮苷类化合物(6aR,11aR)-三叶豆紫檀苷,并运用核磁共振波谱学技术鉴定了其化学结构。采用实验室活体生物试验方法,研究了(6aR,11aR)-三叶豆紫檀苷对马铃薯腐烂茎线虫的麻醉活性。结果表明,该化合物对马铃薯腐烂茎线虫二龄幼虫有一定的麻醉活性,麻醉作用的强度与其浓度及作用时间密切相关。     

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。     

Understanding niche shifts: using current and historical data to model the invasive redlegged earth mite,Halotydeus destructor

Aim Niche conservatism is key to understanding species responses to environmental stress such as climate change or arriving in new geographical space such as biological invasion. Halotydeus destructor is an important agricultural pest in Australia and has been the focus of extensive surveys that suggest this species has undergone a niche shift to expand its invasive range inland to hotter and drier environments. We employ modern correlative modelling methods to examine niche conservatism in H. destructor and highlight ecological differences between historical and current distributions. Location Australia and South Africa. Methods We compile comprehensive distribution data sets for H. destructor, representing the native range in South Africa, its invasive range in Australia in the 1960s (40 yr post‐introduction) and its current range in Australia. Using MAXENT, we build correlative models and reciprocally project them between South Africa and Australia and investigate range expansion with models constructed for historical and current data sets. We use several recently developed model exploration tools to examine the climate similarity between native and invasive ranges and subsequently examine climatic variables that limit distributions. Results The invasive niche of H. destructor in Australia transgresses the native niche in South Africa, and the species has expanded in Australia beyond what is predicted from the native distribution. Our models support the notion that H. destructor has undergone a more recent range shift into hotter and drier inland areas of Australia since establishing a stable distribution in the 1960s. Main conclusions Our use of historical and current data highlights that invasion is an ongoing dynamic process and demonstrates that once a species has reached an established range, it may still expand at a later stage. We also show that model exploration tools help understand factors influencing the range of invasive species. The models generate hypotheses about adaptive shifts in H. destructor.