Asian chestnut gall wasp in Tuscany: gall characteristics,egg distribution and chestnut cultivar susceptibility

• 1 Preliminary investigations were carried out on Dryocosmus kuriphilus Yasumatsu on Castanea sativa Miller in Tuscany to assess variations in gall characteristics in coppice and high forest at two crown heights (height < 2 or 2–6 m), influence of bud size and bud position on oviposition rates and susceptibility of three cultivars.
• 2 Gall size may depend on various factors, including wasp population density. In the present study area, small galls (with one or two cells) were the most numerous in 2008, whereas larger galls (with more than three cells) prevailed in 2009.
• 3 Dryocosmus kuriphilus oviposition occurrence was influenced by both bud size and bud position. Buds with eggs tended to be larger in size compared with bud without eggs, suggesting that D. kuriphilus females prefer to lay eggs in larger buds (approximately 6 mm³) compared with smaller buds (approximately 3 mm³). The mean number of eggs per bud tended to decrease from the apical bud toward the basal bud.
• 4 Three C. sativa cultivars, Carpinese, Fusca and Cesurone, were examined. Fusca grafts had significantly more galls compared with Carpinese and Cesurone, whereas Cesurone grafts had more larvae per bud compared with Carpinese and Fusca. Overall, the Carpinese cultivar may be less susceptible to D. kuriphilus galling compared with the Fusca and Cesurone cultivars.

     

Wolbachia infection shared among planthoppers (Homoptera: Delphacidae) and their endoparasite (Strepsiptera: Elenchidae): a probable case of interspecies transmission

Wolbachia, a group of parasitic bacteria of arthropods, are believed to be horizontally transmitted among arthropod taxa. We present a new probable example of interspecies horizontal transmission of Wolbachia by way of an endoparasite based on the conformity of Wolbachia gene sequences. Field samples of two rice planthoppers, Laodelphax striatellus and Sogatella furcifera possessed identical Wolbachia. Among three major endoparasites of planthoppers, a strepsipteran, Elenchus japonicus, harboured the identical Wolbachia strain, suggesting strepsipteran transmission of Wolbachia from one planthopper to the other. No Wolbachia was detected in a mermithid nematode Agamermis unka, and dryinid wasps possessed different types of Wolbachia.     

High incidences and similar patterns of Wolbachia infection in fig wasp communities from three different continents

Abstract Wolbachia are endosymbiotic bacteria that infect numerous arthropod species. Previous studies in Panama and Australia revealed that the majority of fig wasp species harbor Wolbachia infections, but that similar patterns of incidence have evolved independently with different wasp species and Wolbachia strains on the two continents. We found Wolbachia infections in 25/47 species (53%) of fig wasp associated with 25 species of Chinese figs. Phylogenetic analyses of Wolbachia wsp sequences indicated that very similar strains are not obviously found in either closely related or ecologically linked fig wasps species. The extremely high prevalence of Wolbachia in fig wasps (over 50% of species infected) is not constrained by geographical origin and is a recurrent theme of fig wasp/Wolbachia interactions.     

Insight into the routes of Wolbachia invasion: high levels of horizontal transfer in the spider genus Agelenopsis revealed by Wolbachia strain and mitochondrial DNA diversity

The pandemic distribution of Wolbachia (alpha-proteobacteria) across arthropods is largely due to the ability of these maternally inherited endosymbionts to successfully shift hosts across species boundaries. Yet it remains unclear whether Wolbachia has preferential routes of transfer among species. Here, we examined populations of eight species of the North American funnel-web spider genus Agelenopsis to evaluate whether Wolbachia show evidence for host specificity and the relative contribution of horizontal vs. vertical transmission of strains within and among related host species. Wolbachia strains were characterized by multilocus sequence typing (MLST) and Wolbachia surface protein (WSP) sequences, and analysed in relation to host phylogeny, mitochondrial diversity and geographical range. Results indicate that at least three sets of divergent Wolbachia strains invaded the genus Agelenopsis. After each invasion, the Wolbachia strains preferentially shuffled across species of this host genus by horizontal transfer rather than cospeciation. Decoupling of Wolbachia and host mitochondrial haplotype (mitotypes) evolutionary histories within single species reveals an extensive contribution of horizontal transfer also in the rapid dispersal of Wolbachia among conspecific host populations. These findings provide some of the strongest evidence to support the association of related Wolbachia strains with related hosts by means of both vertical and horizontal strain transmission. Similar analyses across a broader range of invertebrate taxa are needed, using sensitive methods for strain typing such as MLST, to determine if this pattern of Wolbachia dispersal is peculiar to Agelenopsis (or spiders), or is in fact a general pattern in arthropods.     

Wolbachia infection in crustaceans: novel hosts and potential routes for horizontal transmission

Thirty‐five percent of isopods are estimated to be infected by Wolbachia, an intracellular maternally inherited α‐Proteobacterium. Previous studies have indicated that horizontal transfer of Wolbachia strains may occur, although the mechanisms are unclear. The wsp gene was sequenced from 17 Wolbachia strains harboured by crustacean host species and three from their associated predators and parasites. Two major clades of Wolbachia were found in crustacean, with relatives also found in insects, the other restricted to crustaceans. Highly divergent Wolbachia strains were found in a woodlouse‐eating spider and its prey, suggesting no intertaxon bacterial exchange via the predator–prey route. The phylogenetic proximity of Wolbachia from parasitoid flies or phoretic mites to those from isopods suggests that horizontal symbiont transmission may have occurred between those taxa. Two distant Wolbachia strains were detected in two intertidal amphipods; these strains were closely related to different coastal isopod symbionts, suggesting Wolbachia transmission may occur between distantly related crustacean hosts living under the same ecological conditions.     

The diversity,recombination and horizontal transmission of Wolbachia in spiders in China

Wolbachia are maternally inherited endosymbiotic bacteria. These intracellular bacteria are common in arthropods and could manipulate host reproduction in diverse ways, such as feminization, parthenogenesis, male killing and cytoplasmic incompatibility. In spiders, infection by Wolbachia has been found in a total of 99 species belonging to 62 genera and 17 families. Furthermore, recent studies analyzed the phylogeny of Wolbachia in Hylyphantes graminicola, 2 cave spiders and Agelenopsis species using multilocus sequence typing (MLST) approach. However, the diversity of Wolbachia strains determined by MLST in spiders from China is still largely unknown.In this study, we collected 1153 spider individuals from Mangshan in China and screened for Wolbachia in 975 individuals representing 68 spider species belonging to 45 genera of 16 families. We analyzed the phylogenetic relationship between Wolbachia and their host spiders by MLST approach. We found novel infections of Wolbachia in 1 family, 9 genera and 20 species of spiders. We found 13 new Wolbachia strains and suggest that group A is more common than group B in Wolbachia that infect spiders. Our results revealed three recombination events of the concatenated multilocus sequences in Wolbachia that infect spiders. Furthermore, our results demonstrated the phylogenetic incongruence between Wolbachia and spiders, suggesting the horizontal transmission of Wolbachia in spiders.We suggest that recombination and horizontal transmission may play an important role in the diversity and evolution of Wolbachia in spiders.     

湖南三地区麦氏安瘿蜂体内Wolbachia 的感染及其wsp基因序列分析

为检测麦氏安瘿蜂Andricus mairei Kieffer有无Wolbachia感染, 本研究对其岳阳、 长沙和邵阳3种群雌、 雄成虫体内Wolbachia的wsp基因进行了PCR检测, 进而对获得的基因片段进行了序列分析。结果显示, 麦氏安瘿蜂岳阳、 长沙及邵阳种群雌、 雄成虫均有Wolbachia感染, 除邵阳种群雌成虫的感染率为80%之外, 其他均为100%。3个种群Wolbachia的wsp基因序列长度皆为561 bp, 且序列完全一致。麦氏安瘿蜂Wolbachia的wsp基因序列与已知瘿蜂族(Cynipini) Neuroterus macropterus、 Biorhiza pallida及Andricus solitarius （strain 1）以及Synergini族Synergus crassicornis感染的Wolbachia的一致性达95%。除Synergini族Ceroptres cerri感染的Wolbachia属于B群（B group）之外, 瘿蜂感染的Wolbachia均属于A群（A group）。在NJ系统树中, 麦氏安瘿蜂与瘿蜂族Neuroterus macropterus、 Biorhiza pallida和Andricus solitarius （strain 1）及Synergini族Synergus crassicornis感染的Wolbachia聚合在同一分支。此外, 麦氏安瘿蜂岳阳、 长沙和邵阳种群均获得了雌、 雄成虫, 其雌性率分别为15.3%, 12.1%和19.8%, 表现出明显的雄性比偏高。结果提示与瘿蜂族的其他已报道的种类一样, Wolbachia与麦氏安瘿蜂的共生并不诱导其营产雌孤雌生殖。     

Microsporidian infections in Lymantria dispar larvae: interactions and effects of multiple species infections on pathogen horizontal transmission

The interactions in multiple species infections and effects on the horizontal transmission of three microsporidian species, Vairimorpha disparis, Nosema lymantriae and Endoreticulatus schubergi, infecting Lymantria dispar were evaluated in the laboratory. Simultaneous and sequential inoculations of host larvae were performed and the resulting infections were evaluated. Test larvae were exposed to the inoculated larvae to measure horizontal transmission. Dual species infections demonstrated interspecific competition between Nosema and Vairimorpha in the host larvae, but no observable competition occurred between Endoreticulatus and either of the other microsporidian species. Timing of inoculation was an important factor determining the outcome of competition between Nosema and Vairimorpha. The species inoculated first showed a higher rate of successful establishment; a time lag of 7 days between inoculations allowed the first species to essentially exclude the second. The microsporidia differed in efficiency of horizontal transmission. Nosema and Endoreticulatus were transmitted at very high rates, close to 100%. Horizontal transmission of Vairimorpha was less efficient, ranging from 25% to a maximum of 75%. The patterns of infection observed in inoculated larvae were reflected in the test larvae that acquired infections in the horizontal transmission experiments. Competition with Vairimorpha suppressed horizontal transmission of Nosema after simultaneous and sequential inoculation. In simultaneous inoculation experiments Endoreticulatus had no effect on transmission of Nosema and Vairimorpha.     

Rearing,release and settlement prospect in Italy of <Emphasis Type="Italic">Torymus sinensis</Emphasis>, the biological control agent of the chestnut gall wasp <Emphasis Type="Italic">Dryocosmus kuriphilus</Emphasis>

Dryocosmus kuriphilus Yasumatsu (Hymenoptera: Cynipidae), is one of the most serious pests attacking chestnut trees. Recently it was incidentally introduced into Northwest Italy and it is now spreading throughout Europe. This pest was successfully controlled in Japan by introducing a parasitoid, Torymus sinensis Kamijo (Hymenoptera: Torymidae), from China’s mainland. Following this successful experience, the parasitoid was introduced into Italy from Japan. One year of preliminary studies led to a successful method of rearing imported galls with a synchronization between the parasitoid’s emergence and the presence of the target galls in the field. In two consecutive years, a total of 2,117 individuals were released in several sites covering most of the infested area. There are encouraging data about the settlement of the parasitoid and its synchrony with the host’s cycle: from about 64,000 host galls collected in the field over 200 T. sinensis were reared. The role of native parasitoids associated with the chestnut gall pest in its Italian distribution range is also discussed.     

Life cycle,epizootiology, and horizontal transmission of Amblyospora (Microspora: Amblyosporidae) in a univoltine mosquito, Aedes stimulans

Amblyospora infections in Aedes stimulans are transovarially transmitted by females infected in the previous year. Pathogen development in progeny is dimorphic and host sex dependent. In males, the pathogen invades fat body tissue and undergoes an extensive developmental sequence which kills the host and results in the formation of eight haploid spores enclosed in an accessory membrane that are not infectious to other larvae. In females, the pathogen invades host oenocytes and undergoes a simple developmental sequence which has no detrimental affect on longevity, fecundity, oviposition, or egg hatch, and results in the formation of binucleated spores that infect the ovaries and ensure transmission to the next generation. Transovarial transmission is continuous and is the major way in which these microsporidia are maintained from year to year, but is incapable of maintaining infections in breeding populations because of low transmission rates and is not sufficient to account for the types and levels of infection observed in the field. Horizontal transmission is reported for the first time. It occurs sporadically during the early stages of larval subsequently disseminated to oenocytes of adult hosts and are transovarially transmitted by females to filial host generations. This pathway of transmission provides the necessary mechanism whereby these microsporidia can reenter the mosquito population and thus perpetuate themselves.     

Evidence for a recent horizontal transmission and spatial spread of Wolbachia from endemic Rhagoletis cerasi (Diptera: Tephritidae) to invasive Rhagoletis cingulata in Europe

The widespread occurrence of Wolbachia in arthropods and nematodes suggests that this intracellular, maternally inherited endosymbiont has the ability to cross species boundaries. However, direct evidence for such a horizontal transmission of Wolbachia in nature is scarce. Here, we compare the well‐characterized Wolbachia infection of the European cherry fruit fly, Rhagoletis cerasi, with that of the North American eastern cherry fruit fly, Rhagoletis cingulata, recently introduced to Europe. Molecular genetic analysis of Wolbachia based on multilocus sequence typing and the Wolbachia surface protein wsp showed that all R. cingulata individuals are infected with wCin2 identical to wCer2 in R. cerasi. In contrast, wCin1, a strain identical to wCer1 in R. cerasi, was present in several European populations of R. cingulata, but not in any individual from the United States. Surveys of R. cingulata from Germany and Hungary indicated that in some populations, the frequency of wCin1 increased significantly in just a few years with at least two independent horizontal transmission events. This is corroborated by the analysis of the mitochondrial cytochrome oxidase II gene that showed association of wCin1 with two distinct haplotypes in Germany, one of which is also infected with wCin1 in Hungary. In summary, our study provides strong evidence for a very recent inter‐specific Wolbachia transmission with a subsequent spatial spread in field populations.