Geographical overlap of two mitochondrial genomes in Spanish honeybees (Apis mellifera iberica)

Restriction enzyme cleavage maps of mitochondrial DNA from the Spanish honeybee, Apis mellifera iberica (Hymenoptera: Apidae), were compared with those from the European subspecies A. m. mellifera, A. m. ligustica, and A. m. carnica, and the African subspecies A. m. intermissa and A. m. scutellata. The mitochondrial DNA (mtDNA) of the two African subspecies can be distinguished by restriction fragment polymorphisms revealed by Hinf I digests. Two distinct mtDNA types were found among Spanish honeybees: a west European mellifera-like type, which predominates in the north of Spain, and an African intermissa-like type, which predominates in the south. Spain appears to be a region of contact and hybridization between the two subspecies A. m. intermissa and A. m. mellifera, which respectively represent African and west European honeybee lineages. This natural boundary between European and African honeybee populations in the Old World may provide a model for predicting the eventual outcome of the colonization of North America by introduced African honeybees.     

Bacterial diversity in worker adults of Apis mellifera capensis and Apis mellifera scutellata (Insecta: Hymenoptera) assessed using 16S rRNA sequences

High-fidelity PCR of 16S rRNA sequences was used to identify bacteria associated with worker adults of the honeybee subspecies Apis mellifera capensis and Apis mellifera scutellata. An expected approximately 1.5-kb DNA band, representing almost the entire length of the 16S rRNA gene, was amplified from both subspecies and cloned. Ten unique sequences were obtained: one sequence each clustered with Bifidobacterium (Gram-positive eubacteria), Lactobacillus (Gram-positive eubacteria), and Gluconacetobacter (Gram-negative alpha-proteobacteria); two sequences each clustered with Simonsiella (beta-proteobacteria) and Serratia (gamma-proteobacteria); and three sequences each clustered with Bartonella (alpha-proteobacteria). Although the sequences relating to these six bacterial genera initially were obtained from either A. m. capensis or A. m. scutellata or both, newly designed honeybee-specific 16S rRNA primers subsequently amplified all sequences from all individual workers of both subspecies. Attempts to amplify these sequences from eggs have failed. However, the wsp primers designed to amplify Wolbachia DNA from arthropods, including these bees, consistently produced a 0.6-kb DNA band from individual eggs, indicating that amplifiable bacterial DNA was present. Hence, the 10 bacteria could have been acquired orally from workers or from other substrates. This screening of 16S rRNA sequences from A. m. capensis and A. m. scutellata found sequences related to Lactobacillus and Bifidobacterium which previously had been identified from other honeybee subspecies, as well as sequences related to Bartonella, Gluconacetobacter, Simonsiella/Neisseria, and Serratia, which have not been identified previously from honeybees.     

Varying degrees of Apis mellifera ligustica introgression in protected populations of the black honeybee, Apis mellifera mellifera, in northwest Europe

The natural distribution of honeybee subspecies in Europe has been significantly affected by human activities during the last century. Non-native subspecies of honeybees have been introduced and propagated, so that native black honeybee (Apis mellifera mellifera) populations lost their identity by gene-flow or went extinct. After previous studies investigated the remaining gene-pools of native honeybees in France and Spain, we here assess the genetic composition of eight northwest European populations of the black honeybee, using both mitochondrial (restriction fragment length polymorphisms of the intergenic transfer RNAleu-COII region) and nuclear (11 microsatellite loci) markers. Both data sets show that A. m. mellifera populations still exist in Norway, Sweden, Denmark, England, Scotland and Ireland, but that they are threatened by gene flow from commercial honeybees. Both Bayesian admixture analysis of the microsatellite data and DraI-RFLP (restriction fragment length polymorphism) analysis of the intergenic region indicated that gene-flow had hardly occurred in some populations, whereas almost 10% introgression was observed in other populations. The most introgressed population was found on the Danish Island of Laeso, which is the last remaining native Danish population of A. m. mellifera and the only one of the eight investigated populations that is protected by law. We discuss how individual admixture analysis can be used to monitor the restoration of honeybee populations that suffer from unwanted hybridization with non-native subspecies.     

高产王浆西蜂DNA分子中的相关基因标志筛选及其鉴定

为了探讨西蜂与高产王浆相关特异基因标记 ,用 12种随机引物 (P1～P12 )对产王浆量不同的4品系西蜂的基因组DNA进行了RAPD PCR分析 ,分别获得了产王浆量高、低不同西蜂的DNA多态性图谱 ,并从P2 引物的DNA多态性图谱中筛选出一差异DNA片段P2 316bp .将P2 316bp差异DNA片段用地高辛标记制备成探针 ,进行Southern杂交鉴定 .实验显示 ,探针与高产王浆西蜂基因组DNA的扩增产物出现了阳性杂交信号 ,而与低产王浆西蜂基因组DNA的扩增产物未出现阳性杂交信号 .结果表明 ,该差异性基因片段P2 316bp是西蜂高产王浆优良性状相关的遗传标记 ,序列为 30 5个核苷酸 .     

Evolutionary history of the honey bee Apis mellifera inferred from mitochondrial DNA analysis

Variability of mitochondrial DNA (mtDNA) of the honey bee Apis mellifera L. has been investigated by restriction and sequence analyses on a sample of 68 colonies from ten different subspecies. The 19 mtDNA types detected are clustered in three major phylogenetic lineages. These clades correspond well to three groups of populations with distinct geographical distributions: branch A for African subspecies (intermissa, monticola, scutellata, andansonii and capensis), branch C for North Mediterranean subspecies (caucasica, carnica and ligustica) and branch M for the West European populations (mellifera subspecies). These results partially confirm previous hypotheses based on morphometrical and allozymic studies, the main difference concerning North African populations, now assigned to branch A instead of branch M. The pattern of spatial structuring suggests the Middle East as the centre of dispersion of the species, in accordance with the geographic areas of the other species of the same genus. Based on a conservative 2% divergence rate per Myr, the separation of the three branches has been dated at about 1 Myr BP.     

Local honeybee (Apis mellifera mellifera L.) populations in the Urals

The COI-COII intergenic region of mitochondrial DNA (mtDNA) was studied in local honeybee (Apis mellifera mellifera) L. populations from the Middle and Southern Urals. Analysis of bee colonies in these regions revealed apiaries enriched in families descending from A. m. mellifera in the maternal lineage. These results confirm the suggestion of preservation of A. m. mellifera refuges in the Urals and provide grounds for work on the preservation of the gene pool of this bee variety, valuable for all Russia.     

中华蜜蜂蜂毒镇静肽基因的cDNA克隆和表达

从中华蜜蜂 (Apisceranacerana)工蜂毒腺中快速抽提总RNA ,用RT PCR扩增得到大小约为2 5 0bp的cDNA片段 ,测序得到的片段长度为 2 34bp ,为蜂毒前镇静肽原 (preprosecapin)基因编码区的cDNA .以 3′RACE方法 ,扩增和测定了 3′端非编码区 2 19bp序列 .中蜂前镇静肽原cDNA序列与已报道的欧洲意蜂该基因cDNA序列具有 92 %同源性 ,氨基酸序列具有 87%同源性 .代表成熟肽镇静肽的最后 2 5个氨基酸序列 ,中蜂与意蜂同源性为 88% .3′端非编码区cDNA序列与欧洲意蜂序列有 73 1%同源性 .将中华蜜蜂蜂毒镇静肽成熟肽编码区与 3′非编码区部分克隆 ,构建了镇静肽与谷胱甘肽转移酶融合表达的载体pGEX AcSecapin .将载体转化大肠杆菌BL2 1(DE3)进行融合表达 .表达产物与抗GST抗体在 2 9kD处有很强的交叉反应 .大肠杆菌超声破碎后的上清液用SDS PAGE检测到表达的蛋白多为可溶性融合蛋白 ,通过亲和层析柱纯化和凝血酶的切割得到了镇静肽蛋白     

Intraspecies differences in mechanisms of formation of protective processes in the honeybee Apis mellifera

Presented in the work are data on interrace differences in mechanisms of formation of antioxidant and phenoloxidase complexes in honeybees of the Middle Russian (Apis mellifera L.) and Caucasian (Apis mellifera caucasica Gorb.) geographic races. Different degree has been revealed of activation of these complexes depending on their localization in the insect organism and providing different strategy of adaptation to temperature stress. A diverse role of ascorbic acid in regulation of the honeybee protective system has been shown.     

New approach to the mitotype classification in black honeybee <Emphasis Type="Italic">Apis mellifera mellifera</Emphasis> and Iberian honeybee <Emphasis Type="Italic">Apis mellifera iberiensis</Emphasis>

The black honeybee Apis mellifera mellifera L. is today the only subspecies of honeybee which is suitable for commercial breeding in the climatic conditions of Northern Europe with long cold winters. The main problem of the black honeybee in Russia and European countries is the preservation of the indigenous gene pool purity, which is lost as a result of hybridization with subspecies, A. m. caucasica, A. m. carnica, A. m. carpatica, and A. m. armeniaca, introduced from southern regions. Genetic identification of the subspecies will reduce the extent of hybridization and provide the gene pool conservation of the black honeybee. Modern classification of the honeybee mitotypes is mainly based on the combined use of the DraI restriction endonuclease recognition site polymorphism and sequence polymorphism of the mtDNA COI–COII region. We performed a comparative analysis of the mtDNA COI–COII region sequence polymorphism in the honeybees of the evolutionary lineage M from Ural and West European populations of black honeybee A. m. mellifera and Spanish bee A. m. iberiensis. A new approach to the classification of the honeybee M mitotypes was suggested. Using this approach and on the basis of the seven most informative SNPs of the mtDNA COI–COII region, eight honeybee mitotype groups were identified. In addition, it is suggested that this approach will simplify the previously proposed complicated mitotype classification and will make it possible to assess the level of the mitotype diversity and to identify the mitotypes that are the most valuable for the honeybee breeding and rearing.     

Diversity of Apis mellifera Subspecies from Turkey Revealed by Sequence Analysis of Mitochondrial 16s rDNA Region

Mitochondrial DNA sequence variation can be used to infer honeybee evolutionary relationships. In this study, DNA sequence diversity of the mitochondrial 16s rDNA region was investigated in 112 honeybees from 15 populations in Turkey, which is mainly populated with Apis mellifera anatoliaca, A. m. caucasica, and A. m. meda. The study revealed 11 haplotypes for this segment, with 13 variable sites and nine parsimony informative sites. The haplotypes were not discriminated according to their geographical locations in a neighbor-joining dendrogram based on 16s rDNA sequences available in Genbank, but all the haplotypes obtained in this study are clustered with published haplotypes such as A. mellifera TAS (AF214666) and A. m. ligustica (EF116868) and with some unpublished Genbank records (HQ318928, HQ318934, and HQ318938). This study expands the knowledge of the mitochondrial 16s rDNA region, and it presents the first comprehensive sequence analysis of this region in Turkish honeybees.     

Mitochondrial Sequence Characterisation of Australian Commercial and Feral Honeybee Strains, Apis mellifera L. (Hymenoptera: Apidae), in the Context of the Species Worldwide

The history of honeybee ( Apis mellifera ) importations and management in Australia is largely anecdotal and therefore a survey and characterisation of this agriculturally important insect is of value. We give information on the genetic composition of 42 feral and commercial strains by sequencing sections of the ATPase 6, cytochrome oxidase III, cytochrome b and ND2 mitochondrial genes to determine the relationship of the strains to each other. Our phylogenetic analysis shows novel associations between A. m. mellifera, A. m. scutellata, A. m. ligustica and A. m. caucasica.     

Turkish honeybees: genetic variation and evidence for a fourth lineage of Apis mellifera mtDNA

The mtDNA of bees from 84 colonies of Turkish honeybees (Apis mellifera) was surveyed for variation at four diagnostic restriction sites and the sequence of a noncoding intergenic region. These colonies came from 16 locations, ranging from European Turkey and the western Mediterranean coast to the Caucasus Mountains along the Georgian border, the eastern Lake Van region, and the extreme south. Combined restriction site and sequence data revealed four haplotypes. Three haplotypes belonged to the eastern Mediterranean mtDNA lineage. The fourth haplotype, which had a novel restriction site pattern and noncoding sequence, was found in samples from the extreme south, near the Syrian border. We found two different noncoding sequences among the eastern Mediterranean haplotypes. The "Caucasian" sequence matches that described from A. m. caucasica, and the "Anatolian" sequence matches that of A. m. carnica. The frequency of the "Caucasian" sequence was highest (98-100%) in sites near the Georgian border and decreased steeply to the south and west. Elsewhere the Anatolian sequence was found. In European Turkey (Thrace) a restriction site polymorphism previously reported from A. m. carnica in Austria and the Balkans was present at high frequency. A novel mtDNA haplotype with a unique restriction site pattern and noncoding sequence was found among bees from Hatay, in the extreme south near the Syrian border. This haplotype differed from the three previously known lineages of honeybee mtDNA--African, western European, and eastern Mediterranean-and may represent a fourth mitochondrial lineage.     

Mitochondrial DNA variability in the Canary Islands honeybees (Apis mellifera L.)

The mitochondrial DNA (mtDNA) of individuals from 79 colonies of Apis mellifera from five Canary Islands was studied using the Dra I test based on the restriction of PCR products of the tRNAleu–COII intergenic region. Five haplotypes of the African (A) lineage and one of the west European (C) lineage were found. The haplotypes A14 and A15 are described for the first time. These haplotypes have a new P sequence named P₁. The wide distribution and high frequency of haplotype A15 suggest that it is characteristic of the Canarian Archipelago. Sources of haplotype variability of honeybee mtDNA in the Canary Islands (waves of colonization from Africa, queen importations, habitat diversification) are discussed.     

2种蜜蜂和3种胡蜂蜂毒前肥大细胞脱粒肽原基因的克隆及同源性分析

从中华蜜蜂、意大利蜜蜂、大胡蜂、墨胸胡蜂和亚非马蜂5种雌成蜂毒腺中快速抽提总RNA,用RT-PCR方法分别扩增各得到大小约为350bp的cDNA片段,进一步将这5个片段克隆入pGEMT-easy载体,进行测序和序列分析。结果表明：所扩增得到的5个片段长度均为341bp,均包含一个完整的开放阅读框和3′端未编码区的188bp核苷酸序列,证实为5种蜂的蜂毒前肥大细胞脱粒肽原的cDNA。经序列比较,意大利蜜蜂、中华蜜蜂、大胡蜂、墨胸胡蜂和亚非马蜂前肥大细胞脱粒肽原核苷酸序列彼此间的同源性都为90％以上。中华蜜蜂、大胡蜂、墨胸胡蜂和亚非马蜂与意大利蜜蜂的前肥大细胞脱粒肽原氨基酸序列的同源性分别为96％、100％、94％和98％。尽管大胡蜂和墨胸胡蜂与意大利蜜蜂属于不同的科,但它们的肥大细胞脱粒肽却完全相同,而中华蜜蜂与意大利蜜蜂属于同一个属,它们的肥大细胞脱粒肽却不相同。中华蜜蜂和亚非马蜂肥大细胞脱粒肽第5号位的氨基酸为精氨酸,替代了意大利蜜蜂5号位的半胱氨酸,该位置的半胱氨酸与19号位的半胱氨酸组成意大利蜜蜂肥大细胞脱粒肽分子的一个对蛋白活性起重要作用的二硫键。     

Hybrid origins of honeybees from italy (Apis mellifera ligustica) and sicily (A. m. sicula)

The genetic variability of honeybee populations Apis mellifera ligustica, in continental Italy, and of A. m. sicula, in Sicily, was investigated using nuclear (microsatellite) and mitochondrial markers. Six populations (236 individual bees) and 17 populations (664 colonies) were, respectively, analysed using eight microsatellite loci and DraI restriction fragment length polymorphism (RFLP) of the cytochrome oxidase I (COI)-cytochrome oxidase II (COII) region. Microsatellite loci globally confirmed the southeastern European heritage of both subspecies (evolutionary branch C). However, A. m. ligustica mitochondrial DNA (mtDNA) appeared to be a composite of the two European (M and C) lineages over most of the Italian peninsula, and only mitotypes from the African (A) lineage were found in A. m. sicula samples. This demonstrates a hybrid origin for both subspecies. For A. m. ligustica, the most widely exported subspecies, this hybrid origin has long been obscured by the fact that in the main area of queen production (from which most of the previous ligustica bee samples originated) the M mitochondrial lineage is absent, whereas it is present almost everywhere else in Italy. This presents a new view of the evolutionary history of European honeybees. For instance, the Iberian peninsula was considered as the unique refuge for the M branch during the quaternary ice periods. Our results show that the Apennine peninsula played a similar role. The differential distribution of nuclear and mitochondrial markers observed in Italy seems to be a general feature of introgressed honeybee populations. Presumably, it stems from the social nature of the species in which both genome compartments are differentially affected by the two (individual and colonial) reproduction levels.     

Pheromonal dominance and the selection of a socially parasitic honeybee worker lineage (Apis mellifera capensis Esch.)

The recent invasion by self-replicating socially parasitic Cape honeybee workers, Apis mellifera capensis, of colonies of the neighbouring African subspecies Apis mellifera scutellata represents an opportunity to study evolution of intraspecific parasitism in real time. As honeybee workers compete pheromonally for reproductive dominance, and as A. m. capensis workers readily produce queen-like pheromones, we hypothesized that these semiochemicals promoted the evolution of intraspecific social parasitism. Remarkably, the offspring of a single worker became established as a parasite in A. m. scutellata's range. This could have resulted from extreme selection among different clonal parasitic worker lineages. Using pheromonal contest experiments, we show that the selected parasitic lineage dominates in the production of mandibular gland pheromones over all other competitors to which it is exposed. Our results suggest that mandibular gland pheromones played a key role in the evolution of intraspecific social parasitism in the honeybee and in the selection of a single genotype of parasitic workers.     

DNA RFLPs at a highly polymorphic locus distinguish European and African subspecies of the honey bee Apis mellifera L. and suggest geographical origins of New World honey bees

A highly polymorphic locus in the honey bee, Apis mellifera L., was detected with genomic probe pB178. Eighty-five alleles, consisting of Msp I and Dde I RFLPs, were found among the Old and New World bees tested. Forty-one Msp I and 43 Dde I restriction fragment patterns, or variants, were identified. Variants and alleles were discontinuously distributed in Old World European and African subspecies. Principal coordinate analysis of the genetic distances between the alleles resulted in the identification of three distinct groups corresponding to three groups of honey bee races with historically different geographical distributions: east European A. m. ligustica and A. m. caucasica ; west European A. m. mellifera ; and South African A. m. scutellata . The clustering of alleles into these groups is consistent with previous honey bee phylogeographic studies, employing other nuclear and mitochondrial DNA markers, which in part support the evolutionary history of the honey bee hypothesized by Ruttner based on morphometric and allozyme data. The majority of alleles in bees from the USA grouped with those found in east European bees, while other alleles grouped with alleles found in A. m. mellifera . While the majority of the alleles in neotropical bees grouped with or were identical to African alleles, other alleles grouped with alleles found in A. m. mellifera, A. m. ligustica , and A. m. caucasica . Clues to the ancestry of neotropical bees may be found in the identification of alleles that were identical or more similar to alleles found in South African and west European bees; evidence for west European ancestry has been suggested using other taxonomic characters that were not unique to west European bees. Both west European and African alleles were found in individual neotropical colonies, which may indicate that honey bee subspecies which evolved allopatrically have hybridized in the human-assisted extension of their original geographical ranges.     

中华蜜蜂和意大利蜜蜂蜂毒前溶血肽原蛋白cDNA的克隆与序列分析

分别从中华蜜蜂Apis cerana cerana和意大利蜜蜂Apis mellifera工蜂毒腺中抽提总RNA,通过RT-PCR方法扩增,各得到了蜂毒前溶血肽原蛋白的cDNA,再将扩增产物克隆到pGEM-Teasy载体上,进行测序和序列分析。结果表明,所扩增到的这两个片段长度均为213 bp,均为编码蜂毒前溶血肽原的cDNA,并分别推导出两者所编码的氨基酸序列。经序列比较,中华蜜蜂前溶血肽原与意大利蜜蜂、印度蜜蜂Apis cerana indica前溶血肽原的同源性都为97%。所报道的中华蜜蜂蜂毒前溶血肽原的核苷酸序列的GenBank登录号为AF487907。     

Inheritance of traits associated with reproductive potential in Apis mellifera capensis and Apis mellifera scutellata workers

When workers of the thelytokous Cape honeybee, Apis mellifera capensis, come into contact with colonies of the neighboring arrhenotokous subspecies Apis mellifera scutellata, they can become lethal social parasites. We examined the inheritance of 3 traits (number of ovarioles, number of basitarsal hairs, and size of spermatheca) that are thought to be associated with reproductive potential in A. m. capensis workers. To do so, we produced hybrid A. m. scutellata/A. m. capensis queens and backcrossed them to either A. m. capensis or A. m. scutellata drones. We then measured the 3 traits in parental, hybrid, and backcross offspring. We show that the 3 traits are phenotypically correlated. We also show that the expression of ovariole number, basitarsal hairs, and size of spermatheca is influenced by the genotype of the individual and the rearing environment but that the influence of the rearing environment is less important to the number of ovarioles. We hypothesize a single recessive allele (l), present at high frequency in natural A. m. capensis populations, which when homozygous causes larvae to elicit more food. This increased feeding as larvae causes resulting adult workers to develop more queen-like morphology and increased reproductive potential. The number of ovarioles, in contrast, appears to be under independent genetic control.     

Monthly changes in various drone characteristics of Apis mellifera ligustica and Apis mellifera syriaca

This study was conducted to investigate drone rearing activity and semen production of Apis mellifera ligustica and Apis mellifera syriaca . Tendency of worker bees of both subspecies towards egg laying under semiarid conditions were also monitored in the experiments. Differences were not observed in drone brood production between both honeybee subspecies throughout the investigation. Worker bees of both subspecies needed a significantly shorter time to start egg laying during February and March in comparison with the time those workers needed for laying eggs during the remaining months of the study. Syrian bee workers started egg laying earlier than Italian bee workers. Drones from laying workers were much smaller and produced less sperms with more abnormalities than normal drones. Drones produced from queens in May were heavier and produced more sperms with less abnormalities than those produced during the other months. The drone brood rearing of both subspecies tended to follow the same general cycle in 2005 and 2006. The study suggests that virgin queens have a better chance to receive adequate viable sperm amounts from drones in April and May in semiarid Mediterranean conditions.