Fecal Microflora from Dragonflies and Its Microorganisms Producing Carotenoids.

The intestines of insects are assumed to be the niche of various microbial groups, and a unique microflora could be formed under environmental conditions different from mammalian intestinal tracts. This chapter describes the bacterial flora formed in the intestines of two dragonfly species, "akatombo" (the red dragonfly; Sympetrum frequens) and "usubaki-tombo" (Pantala flavescens), which fly over a long distance, and carotenoid-producing microorganisms isolated from this flora. C30 carotenoids, which were produced by a bacterium Kurthia gibsonii isolated from S. frequens, were structurally determined.

Phytotoxic and Antifungal Metabolites from Curvularia crepinii QTYC-1 Isolated from the Gut of Pantala flavescens.

Four metabolites (1⁻4), including a new macrolide, O-demethylated-zeaenol (2), and three known compounds, zeaenol (1), adenosine (3), and ergosta-5,7,22-trien-3b-ol (4) were isolated and purified from Curvularia crepinii QTYC-1, a fungus residing in the gut of Pantala flavescens. The structures of isolated compounds were identified on the basis of extensive spectroscopic analysis and by comparison of the corresponding data with those reported in the literature previously. The new compound 2 showed good phytotoxic activity against Echinochloa crusgalli with an IC50 value of less than 5 µg/mL, which was comparable to that of positive 2,4-dichlorophenoxyacetic acid (2,4-D). Compound 1 exhibited moderate herbicidal activity against E. crusgalli with an IC50 value of 28.8 µg/mL. Furthermore, the new metabolite 2 was found to possess moderate antifungal activity against Valsa mali at the concentration of 100 µg/mL, with the inhibition rate of 50%. These results suggest that the new macrolide 2 and the known compound 1 have potential to be used as biocontrol agents in agriculture.

Long-range seasonal migration in insects: mechanisms, evolutionary drivers and ecological consequences.

Myriad tiny insect species take to the air to engage in windborne migration, but entomology also has its 'charismatic megafauna' of butterflies, large moths, dragonflies and locusts. The spectacular migrations of large day-flying insects have long fascinated humankind, and since the advent of radar entomology much has been revealed about high-altitude night-time insect migrations. Over the last decade, there have been significant advances in insect migration research, which we review here. In particular, we highlight: (1) notable improvements in our understanding of lepidopteran navigation strategies, including the hitherto unsuspected capabilities of high-altitude migrants to select favourable winds and orientate adaptively, (2) progress in unravelling the neuronal mechanisms underlying sun compass orientation and in identifying the genetic complex underpinning key traits associated with migration behaviour and performance in the monarch butterfly, and (3) improvements in our knowledge of the multifaceted interactions between disease agents and insect migrants, in terms of direct effects on migration success and pathogen spread, and indirect effects on the evolution of migratory systems. We conclude by highlighting the progress that can be made through inter-phyla comparisons, and identify future research areas that will enhance our understanding of insect migration strategies within an eco-evolutionary perspective.

Linking phenological shifts to species interactions through size-mediated priority effects.

Interannual variation in seasonal weather patterns causes shifts in the relative timing of phenological events of species within communities, but we currently lack a mechanistic understanding of how these phenological shifts affect species interactions. Identifying these mechanisms is critical to predicting how interannual variation affects populations and communities. Species' phenologies, particularly the timing of offspring arrival, play an important role in the annual cycles of community assembly. We hypothesize that shifts in relative arrival of offspring can alter interspecific interactions through a mechanism called size-mediated priority effects (SMPE), in which individuals that arrive earlier can grow to achieve a body size advantage over those that arrive later. In this study, we used an experimental approach to isolate and quantify the importance of SMPE for species interactions. Specifically, we simulated shifts in relative arrival of the nymphs of two dragonfly species to determine the consequences for their interactions as intraguild predators. We found that shifts in relative arrival altered not only predation strength but also the nature of predator-prey interactions. When arrival differences were great, SMPE allowed the early arriver to prey intensely upon the late arriver, causing exclusion of the late arriver from nearly all habitats. As arrival differences decreased, the early arriver's size advantage also decreased. When arrival differences were smallest, there was mutual predation, and the two species coexisted in similar abundances across habitats. Importantly, we also found a nonlinear scaling relationship between shifts in relative arrival and predation strength. Specifically, small shifts in relative arrival caused large changes in predation strength while subsequent changes had relatively minor effects. These results demonstrate that SMPE can alter not only the outcome of interactions but also the demographic rates of species and the structure of communities. Elucidating the mechanisms that link phenological shifts to species interactions is crucial for understanding the dynamics of seasonal communities as well as for predicting the effects of climate change on these communities.

The first complete mitochondrial genome of the migratory dragonfly Pantala flavescens Fabricius, 1798 (Libellulidae: Odonata).

Pantala flavescens is the world's most abundant and widely distributed dragonfly and with its outstanding migratory capacity an important model system to study insect migration at the evolutionary base of winged insects. We here report on the first complete mitochondrial genome (mitogenome) of P. flavescens sampled from a population in Rufiji River, Tanzania. The mitogenome is 14,853 bp long with an AT-biased base composition (72.7% A + T) and encodes a typical set of 13 protein-coding genes (PCGs), 22 tRNAs, and two rRNAs. The control region (CR) (171 bp) is the shortest reported in any anisopteran odonate, so far. Phylogenetic analyses support the placement of P. flavescens within the Libellulidae.

Dragonfly-Associated Trichoderma harzianum QTYC77 Is Not Only a Potential Biological Control Agent of Fusarium oxysporum f. sp. cucumerinum But Also a Source of New Antibacterial Agents.

A strain isolated from the gut of Pantala flavescens was characterized as Trichoderma harzianum QTYC77. The strain was assessed as a potential biocontrol agent against Fusarium oxysporum f. sp. cucumerinum (FOC). Mycoparasitism and competing abilities of T. harzianum QTYC77 lead to inhibition of the mycelial growth of FOC, with the inhibition rate of 70.99%, in dual culture assays. Activities of chitinase and ß-1,3-glucanase, responsible for fungal cell-wall degradation, were gradually increased and their activities were the maximum on the fifth day of fermentation with 23.20 and 1.84 U/mL, respectively. T. harzianum QTYC77 was discovered to have potent biocontrol potential with the control efficiency of 67.43% against the FOC in vivo pot experiment. Furthermore, two novel compounds azaphilone D (1) and E (2) along with three known metabolites 3-hydroxymethyl-6, 8-dimethoxycoumarin (3), harzianone (4), and pachybasin (5) were isolated and identified from T. harzianum QTYC77. Unfortunately, these metabolites did not show antifungal activities against FOC. However, both metabolites 1 and 3 displayed moderate activity against Staphylococcus aureus with disc diameters of zone of inhibition (ZOI) of 7.3 and 7.2 mm, respectively, compared with that of referenced gentamycin (ZOI = 14.5 mm). In addition, metabolite 1 possessed a moderate antibacterial activity against Bacillus subtilis with a ZOI value of 7.0 mm compared with that of positive gentamycin (ZOI = 15.2 mm). The present results suggested that T. harzianum QTYC77 was not only a potential biofungicide against FOC but also the source of new antibacterial agents.

Influence of aquatic plants on the predation of Piaractusmesopotamicus larvae by Pantala flavescens / Influência de macrófitas aquáticas na predação de larvas de Piaractus mesopotamicus por Pantala flavescens

The experiment aimed to study the influence of the aquatic plants E. najas,P. stratiotes and S. auriculata on the predation of P. mesopotamicus larvae by P. flavescens. Onehundred and twenty larvae of P. mesopotamicus and 24 larvae of P. flavescens were placed in 24aquariums with capacity of 12 L, with one Odonate per aquarium. Treatments weredifferent regarding the species of aquatic plants E. najas, S. auriculata and P. stratiotes, withone control treatment without aquatic plants. One aquarium (12 L) containing oneOdonate and 30 P. mesopotamicus larvae was considered one experimental unit. After 18hours, the Odonates were removed from the aquariums and fish larvae left (alive) werecounted in each experimental unit. The survival rate of P. mesopotamicus larvae in thetreatment without aquatic plants (control) was significantly lower than in the treatmentwith E. najas. However, the survival rates in the aquariums with floating aquatic plants didnot differ from the control. The morphological characteristics of E. najas promoted higherstructural complexity in the environment, offering more protection to the fish larvae, andincreasing their survival. We concluded that the presence of the submerged aquatic plant E.najas promoted the reduction of predation of P. mesopotamicus larvae by Pantala flavescens.

O experimento teve como objetivo estudar ainfluência de macrófitas aquáticas na predação de larvas de peixe P. mesopotamicus por larvasde P. flavescens Foram utilizadas 720 larvas de P. mesopotamicus e 24 larvas de P. flavescens,distribuídas em 24 aquários com volume útil para 12 L, sendo colocada uma larva deOdonata por aquário. Os tratamentos diferiram quanto à espécie de macrófita E. najas (E),S. auriculata (S) e P. stratiotes (P) sendo mantido um tratamento controle (C) sem macrófitas.Um aquário contendo uma larva de Odonata e 30 larvas de P. mesopotamicus foi consideradouma unidade experimental. Após 18 horas do início do experimento, as Odonatas foramretiradas dos aquários e foi realizada a contagem das larvas de peixe remanescentes (vivas)em cada unidade experimental. A taxa de sobrevivência das larvas de P. mesopotamicus notratamento sem macrófita (controle) foi significativamente menor quando comparada aotratamento contendo a macrófita submersa E. najas. Entretanto o valor de sobrevivência nosaquários com macrófitas flutuantes não diferiu do controle. As características morfológicasda E. najas promoveram uma maior complexidade estrutural no ambiente, gerando ummaior numero de abrigos para as larvas de peixe, aumentando assim a sobrevivência dasmesmas. Conclui-se que a presença da macrófita aquática E. najas promove redução napredação das larvas de P. mesopotamicus por larvas de P. flavescens.