Characterization of a new insect cell line that is derived from the neonate larvae of Papilio xuthus (Lepidoptera: Papilionidae) and its susceptibility to AcNPV

The cell line RIRI-PX1 was established from neonate larval tissues of Papilio xuthus by performing primary cultures in the modified Grace medium that was supplemented with 20% fetal bovine serum (FBS). The cell line primarily consisted of spindle-shaped and spherical cells which attached themselves to the flask. The population-doubling times (PDTs) at the 50th and 60th passage were 42.5 h and 42.1 h respectively. The average chromosome numbers of RIRI-PX1 cell line from passage 5 to passage 50 ranged from 103 to 199. It was confirmed that RIRI-PX1 cell line was derived from P. xuthus by comparing the mitochondrial cytochrome c oxidase subunit I gene (COI) of RIRI-PX1 cells and P. xuthus eggs. This cell line was susceptible to the Autographa californica nucleopolyhedrovirus (AcNPV) and produced high yield of polyhedral occlusion bodies (43.9 OBs/cell) after 10 days of infection by AcNPV. The virus titer of AcNPV infected RIRI-PX1 cells was 3.25 × 10⁷ TCID₅₀/ml. We concluded that the RIRI-PX1 cell line is established from the neonate larvae tissues successfully and the cells of the cell line are sensitive to AcNPV.     

Diversification of host use in two polyphagous butterflies: differences in oviposition specificity or host rank hierarchy?

Novel host usage may represent an initial step towards diversification or radiation onto novel hosts within an evolutionary lineage, particularly if a shift in host plant preference ranking takes place. Polyphagous stages of evolutionary lineages may represent transitional states in which novel host associations are more likely to develop, but may be more difficult to detect experimentally. The polyphagous sister species Papilio glaucus L. and Papilio canadensis (Lepidoptera: Papilionidae; these Papilio = Pterourus) are known to exhibit differences in host‐plant use, despite significant overlap in host‐use abilities, providing an opportunity to examine how host shifts in polyphagous species may occur and what the implications for future divergence may be. In particular, we were interested in (i) determining whether differences in oviposition behavior of these species were due to changes in specificity or shifts in host‐plant hierarchy, (ii) whether the varying preference for primary hosts also affected the preference for secondary hosts, and (iii) what the oviposition preferences of a new hybrid swarm population are. We examined more than 40 000 oviposition bouts from more than 400 P. glaucus, P. canadensis, and hybrid females placed in seven‐, three‐, or two‐choice assays. In each of the choice assays, leaves from plants in different plant families of varying suitability for P. glaucus and P. canadensis larvae were used. We found the primary difference between P. glaucus and P. canadensis to be limited to a Z‐linked shift in host rank hierarchy due to an acceptance of Populus tremuloides Michx. (Salicaceae) and reduced specificity for Liriodendron tulipifera L. (Magnoliaceae) in P. canadensis. In addition, we found the absence of the Z‐linked oviposition acceptance of P. tremuloides in a recently formed allochronically separated hybrid swarm population found in P. canadensis territory at the northern border of the P. glaucus and P. canadensis hybrid zone.     

The evolution of diet breadth: Monophagy and polyphagy in swallowtail butterflies

Much of the world's biodiversity has resulted from specialization of insect populations onto different plant species, partially through evolution of preference in ovipositing females. Here I report an experimental analysis of how an oviposition preference hierarchy has evolved during the evolutionary diversification of an insect group to produce taxa ranging from monophagous to polyphagous. Tests on the Papilio machaon group of swallowtail butterflies show that the preference hierarchy for plant species is evolutionarily dynamic within this species complex, yet constrained among most populations within species, creating a geographic mosaic of populations differing to various degrees in patterns of host preference. The results indicate that different diet breadths can evolve within a group of closely-related species through a combination of conservatism in preference hierarchy among some populations, occasional but rare rearrangements in preference among others, correlations in preference for some plant species, and availability of similarly ranked hosts.     

Differential responses of tiger swallowtail subspecies to secondary metabolites from tulip tree and quaking aspen

Summary Two subspecies of the eastern tiger swallowtail butterfly, Papilio glaucus, exhibit reciprocal inabilities to survive and grow on each other's preferred foodplant. P. g. canadensis R. & J. performs well on quaking aspen (Populus tremuloides Michx.) but not on tulip tree (Liriodendron tulipifera L.); P. g. glaucus L. performs well on tulip tree but not on quaking aspen. This study was designed to test the hypothesis that secondary metabolites in tulip tree and quaking aspen are responsible for these differential utilization abilities. We extracted and fractionated leaf constituents into different chemical classes, applied them to a mutually acceptable diet (black cherry, Prunus serotina, leaves), and bioassayed them against neonate larvae (survival) and penultimate instar larvae (survival, growth, digestibility and conversion efficiencies). For each plant species, one fraction in particular showed activity against the unadapted subspecies. One tulip tree fraction dramatically reduced survival of P. g. canadensis neonates, and reduced consumption rates, growth rates, and ECI's of fourth instar larvae. The tulip tree constituents most likely responsible for these effects are sesquiterpene lactones. One quaking aspen fraction greatly lowered survival of P. g. glaucus neonates, and decreased survival, consumption rates, growth rates and ECD's of fourth instar larvae. The compounds responsible for these results are probably simple phenols or phenolic glycosides. Surprisingly, P. g. glaucus and P. g. canadensis showed slightly poorer performance on the active tulip tree and quaking aspen fractions, respectively, indicating that even adapted insects incur a metabolic cost in the processing of their host's phytochemicals.     

Characterization of 17 polymorphic microsatellite loci in the Anise swallowtail,Papilio zelicaon (Lepidoptera: Papilionidae), and their amplification in related species

Fifteen polymorphic dinucleotide and two trinucleotide microsatellite loci were identified in the Anise swallowtail, Papilio zelicaon, from DNA genomic libraries enriched for simple sequence repeats. Allele numbers varied from eight to 29, with an excess of homozygotes observed for nine loci. This homozygosity is a feature of other lepidopteran microsatellites and is probably due to null alleles. Sixteen markers were amplified successfully in other representatives of Papilio with 11 loci retaining polymorphism in at least one species. These results suggest that the microsatellites reported here may be appropriate for measuring population genetic structure in a number of Papilio species.     

Essential oil composition of nine Apiaceae species from western United States that attract the female Indra Swallowtail butterfly (Papilio indra)

Aletes acaulis, Cymopterus hendersonii, Cymopterus panamintensis var. acutifolius, Lomatium rigidum, Lomatium scabrum var. tripinnatum, Musineon tenuifolium, Sphenosciadium capitellatum, Tauschia arguta and Tauschia parishii are among the twenty-two species of the Apiaceae family to which female Indra Swallowtail butterflies (Papilio indra: Lepidoptera) are attracted for oviposition. Because plant volatile oils are known to be attractants for female butterflies, the percent composition of the essential oils of each species was studied. Amongst the nine host plants 168 essential oil components were identified representing between 84% and 99% of the oils. Principal Components Analysis and hierarchical cluster analysis on the essential oil compositions of the larval host plants against four non-larval host plants separated the hosts from the non-hosts into distinct clusters. Volatile components of the oils common to the nine species of Apiaceae are correlated with the expression of physiological attraction behavior by the butterfly.     

利用ENFA生态位模型分析玉带凤蝶和箭环蝶异地放飞的适生性

活体蝴蝶异地放飞存在潜在的入侵风险。本文采用生态位因素分析（ENFA）模型分析包括气候、地形、生境结构、植被类型、人类活动在内的影响玉带凤蝶Papilio polytes Linnaeus和箭环蝶Stichophthalma howqua(Westwood) 两种放飞蝴蝶分布的生态地理变量,模拟其在中国的适宜生境,评估其入侵风险。对现有分布记录的分析表明： 影响这两种蝴蝶分布的主要环境变量与其生态学特性相一致,且影响其扩散范围的主要因素为年总积温和冬季低温等;同时,人类活动的干扰对其分布影响很大。根据适生性图推测,这两种蝴蝶的适宜生境大部分重叠,主要集中在中国大陆中部及东南部,其扩散趋势由东南向西北发展。为防止活体蝴蝶放飞带来的潜在入侵风险,根据不同适生等级提出：HSI≥50的地方,不能开展室外放飞;5≤HSI<50的地方,可采取限制性室外放飞; HSI<5的地方,可进行自由室外放飞。     

Enemy-free space and habitat-specific host specialization in a butterfly

The majority of herbivorous insects have relatively specialized food habits. This suggests that specialization has some advantage(s) over generalization. Traditionally, feeding specialization has been thought to be linked to digestive or other food-related physiological advantages, but recent theory suggests that generalist natural enemies of herbivorous insects can also provide a major selective pressure for restricted host plant range. The European swallowtail butterfly Papilio machaon utilizes various plants in the Apiaceae family as hosts, but is an ecological specialist being monophagous on Angelica archangelica in southern Sweden. This perennial monocarp grows in three seaside habitat types: (1) on the barren rocky shore in the absence of any surrounding vegetation, (2) on the rocky shore with some surrounding vegetation, and (3) on species-rich meadows. The rocky shore habitat harbors few invertebrate generalist predators, whereas a number of invertebrate predators abound in the meadowland habitat. Here, we test the importance of enemy-free space for feeding specialization in Papilio machaon by assessing survival of larvae placed by hand on A. archangelica in each of the three habitat types, and by assessing the habitat-specificity of adult female egg-laying behavior by recording the distribution of eggs laid by free-flying adult females among the three habitat types. Larval survival was substantially higher in the rocky shore habitat than in the meadowland and significantly higher on host plants without surrounding vegetation on the rocky shore. Eggs laid by free-flying females were found in all three habitat types, but were significantly more frequent in the rocky shore habitat, suggesting that females prefer to lay eggs in the habitat type where offspring survival is highest. These results show that larval survivorship on the same host plant species can be strongly habitat-specific, and suggest that enemy-free space is an underlying factor that drives feeding specialization in Papilio machaon.     

Interactions between Papilionidae and ancient Australian Angiosperms: evolutionary specialization or ecological monophagy?

The evolution of host range for insect herbivores involves many behavioral, physiological, and biochemical adaptations that often lead to locally specialized populations or species. Such specialization may be constrained by ecological factors (e.g., local host availability) or by evolutionary factors (e.g., phylogenetic divergence in behavioral, physiological, or biochemical detoxification enzymes; and potential inabilities to return to ancestral hosts). While insect adaptations to new hosts can be rapid, ancient detoxification systems may persist in some lineages of swallowtail butterflies (Papilionidae) for millions of years. Here, we test various species of specialized species/populations of Papilionidae (Lepidoptera) from North America and from Australia on an array of Australian host plant families in order to determine whether the current feeding constraints reflect loss of capabilities to recognize and use hosts other than their current (local) favorites. We selected two species of Lauraceae specialists (Papilio troilus L. and Papilio palamedes Drury) from North America and one locally specialized population of Papilio glaucus L. that only uses one plant species in the Magnoliaceae in Florida. We also examined three species/populations of Australian swallowtails for comparison, including the Monimiaceae‐specialized Graphium macleayanum moggana L. E. Couchman, the Rutaceae‐specialized Papilio aegeus Donovan, and the Annonaceae‐specialized Graphium eurypylus L. Our aim was to determine whether neonate larvae of these six specialists could survive on any plants other than their currently favored species. While the Lauraceae specialists could use nothing else and were thus evolutionarily constrained, the Magnoliaceae‐, Rutaceae‐, and Monimiaceae specialists all had common abilities to accept, feed, and grow on plants in the Lauraceae, Monimiaceae, Magnoliaceae, and Rutaceae families. Even the Annonaceae specialist was discovered using Magnoliaceae in the field, suggesting existence here also of both flexiblity in preferences and detoxification abilities and ‘ecological monophagy’.