Matthias W. Lorenz

A Family of Neuropeptides That Inhibit Juvenile Hormone Biosynthesis in the Cricket, Gryllus bimaculatus

Four nonapeptides that inhibit juvenile hormone synthesis have been isolated by four high performance liquid chromatographic steps from extracts of the brain of the field cricket, Gryllus bimaculatus. The primary structures of these peptides were assigned by Edman degradation and mass spectrometry as Gly-Trp-Gln-Asp-Leu-Asn-Gly-Gly-Trp-NH2 (Grb-AST B1), Gly-Trp-Arg-Asp-Leu-Asn-Gly-Gly-Trp-NH2 (Grb-AST B2), Ala-Trp-Arg-Asp-Leu-Ser-Gly-Gly-Trp-NH2 (Grb-AST B3), and Ala-Trp-Glu-Arg-Phe-His-Gly-Ser-Trp-NH2 (Grb-AST B4). Each of the peptides shows high sequence similarity to the locustamyoinhibiting peptide (Lom-MIP), but is structurally different from all the allatostatins so far identified. The synthetic allatostatins Grb-AST B1-4 are potent inhibitors (50% inhibition at 10 to 7 10M) of juvenile hormone III biosynthesis by corpora allata from 3-day-old virgin females of G. bimaculatus using an in vitro bioassay. At 10M, Grb-AST B1 also strongly inhibits juvenile hormone III biosynthesis by corpora allata from 2-day-old adult males and 1-day-old (males and females) and 4-day-old (females) last instar larvae of G. bimaculatus. The inhibitory effect of Grb-AST B1 was also evident on corpora allata from a related species, Acheta domesticus. Inhibition of juvenile hormone synthesis by Grb-AST B1-4 is reversible.

Identification of two allatostatins from the cricket, Gryllus bimaculatus de Geer (Ensifera, Gryllidae): additional members of a family of neuropeptides inhibiting juvenile hormone biosynthesis.

Two peptide inhibitors of juvenile hormone biosynthesis, designated G. bimaculatus allatostatins A1 and A2, have been purified from extracts of the brain of the field cricket Gryllus bimaculatus. The primary structures of these peptides were assigned as Ala-Gln-His-Gln-Tyr-Ser-Phe-Gly-Leu-NH2 (Grb-AST A1) and Ala-Gly-Gly-Arg-Gln-Tyr-Gly-Phe-Gly-Leu-NH2 (Grb-AST A2). Each of the peptides shows C-terminal amino acid sequence similarity to cockroach allatostatins and blowfly callatostatins. The two peptides are potent inhibitors of in vitro juvenile hormone production by corpora allata from virgin females of G. bimaculatus.

Adipokinetic hormone inhibits the formation of energy stores and egg production in the cricket Gryllus bimaculatus

Adipokinetic hormones (AKHs) mobilise lipids, carbohydrates and/or proline from insect fat body stores. In addition, AKHs inhibit lipid and protein synthesis in the fat body. In the current study, 100 pmol homologous Grybi-AKH was injected twice daily into adult female crickets, Gryllus bimaculatus, starting on the day of adult emergence. The effects of the injected AKH on the formation of energy reserves in the fat body and on egg production were measured on day 4 after adult emergence. In comparison to water-injected control animals, lipid and protein content in the fat body of the AKH-injected crickets was significantly reduced, suggesting an inhibitory effect of AKH on the formation of lipid reserves and protein stores. The content of glycogen and free carbohydrate in the fat body was significantly higher in the AKH-injected animals. The most pronounced effect of the AKH-injections was a significant reduction of ovary mass, due to the retarded maturation of the oocytes and the significantly lower number of terminal oocytes produced. It is concluded that AKH inhibits egg production indirectly by interference with the formation of energy stores in the fat body that are mobilised to fuel egg production.

Recent Advances in Hormones in Insect Pest Control

New approaches to the development of insect control agents have been revealed through the description of natural and synthetic compounds capable of interfering with the processes of development and reproduction of the target insects. The review presents information on novel insecticides that mimic the action of two insect growth and developmental hormone classes, the ecdysteroids and the juvenile hormones. Neuropeptide structures, their biogenesis, action, and metabolism also offer the opportunity to exploit novel control agents.

Hormonal regulation of energy metabolism in insects as a driving force for performance

Since all life processes depend on energy, the endocrine control of energy metabolism is one of the driving forces for the performance of an individual. Here, we review the literature on the key players in the endocrine regulation of energy homeostasis in insects, the adipokinetic hormones. These pleiotropic peptides not only control dynamic performance traits (flight, swimming, walking) but also regulatory performance traits (egg production, larval growth, and molting). Adipokinetic hormone is released into the hemolymph during intense muscular activity (flight) and also during apparently less energy-demanding locomotory activities, such as swimming and even walking, and, finally, activates the catabolic enzymes phosphorylase and/or triacylglycerol lipase that mobilize carbohydrates and/or lipids and proline, respectively. At the same time, anabolic processes such as the synthesis of protein, lipid, and glycogen are inhibited. Furthermore, adipokinetic hormones affect locomotory activity via neuromodulatory mechanisms that apparently employ biogenic amines. During oogenesis, it is thought that adipokinetic hormone performs similar tasks, because energetic substrates have to be mobilized and transported from the fat body to the ovaries in order to support oocyte growth. Inhibition of anabolic processes by exogenous adipokinetic hormone results in females that lay fewer and smaller eggs. Much less is known about the role of adipokinetic hormones during larval development and during molting but in this case energy homeostasis has to be tightly regulated as well: in general, during the early phase of a larval instar intake of food prevails and the energy stores of the fat body are established, whereas, prior to the molt, insects stop feeding and mobilize energy stores in the fat body, thereby fueling energy-demanding processes such as the formation of the new cuticle and the emergence from the old one. From the few data available to date, it is clear that adipokinetic hormones are involved in the regulation of these events in larvae.

Adult nutrition and butterfly fitness: effects of diet quality on reproductive output, egg composition, and egg hatching success

BackgroundIn the Lepidoptera it was historically believed that adult butterflies rely primarily on larval-derived nutrients for reproduction and somatic maintenance. However, recent studies highlight the complex interactions between storage reserves and adult income, and that the latter may contribute significantly to reproduction. Effects of adult diet were commonly assessed by determining the number and/or size of the eggs produced, whilst its consequences for egg composition and offspring viability were largely neglected (as is generally true for insects). We here specifically focus on these latter issues by using the fruit-feeding tropical butterfly Bicyclus anynana, which is highly dependent on adult-derived carbohydrates for reproduction.ResultsAdult diet of female B. anynana had pronounced effects on fecundity, egg composition and egg hatching success, with butterflies feeding on the complex nutrition of banana fruit performing best. Adding vitamins and minerals to a sucrose-based diet increased fecundity, but not offspring viability. All other groups (plain sucrose solution, sucrose solution enriched with lipids or yeast) had a substantially lower fecundity and egg hatching success compared to the banana group. Differences were particularly pronounced later in life, presumably indicating the depletion of essential nutrients in sucrose-fed females. Effects of adult diet on egg composition were not straightforward, indicating complex interactions among specific compounds. There was some evidence that total egg energy and water content were related to hatching success, while egg protein, lipid, glycogen and free carbohydrate content did not seem to limit successful development.ConclusionThe patterns shown here exemplify the complexity of reproductive resource allocation in B. anynana, and the need to consider egg composition and offspring viability when trying to estimate the effects of adult nutrition on fitness in this butterfly and other insects.

Allatotropic activity in the suboesophageal ganglia of crickets, Gryllus bimaculatus and Acheta domesticus (Ensifera: Gryllidae)

Abstract Corpora allata from young male Gryllus bimaculatus were tested for their ability to synthesize juvenile hormone III and to respond to stimulating suboesophageal ganglia extracts in vitro . Corpora allata from day-0 males (3–12 h after ecdysis) exhibit a low basal juvenile hormone III biosynthetic activity and respond consistently and very well to allatotropic stimulation. The stimulatory action is rapid and dose-dependent. A maximum allatotropic activity is present in the suboesophageal ganglia of 3-day-old females, at the time when juvenile hormone III biosynthesis is also highest. Suboesophageal ganglia extracts prepared from males are almost equally effective during the first 5 days after the imaginal moult. A calcium ion concentration of 2.5 mM in the incubation medium supports the allatotropic activity of the suboesophageal ganglia extract in an additive way. Based on its proteinase K sensitivity and heat stability, the allatotropic factor is most likely a peptide. The allatotropin has been partly purified by Sep-Pak C 18 fractionation and reversed-phase HPLC. Extracts prepared from the suboesophageal ganglia of the house cricket, Acheta domesticus , stimulate juvenile hormone III biosynthesis in corpora allata of G. bimaculatus and vice versa .

Effects of temperature on reproductive output, egg provisioning, juvenile hormone and vitellogenin titres in the butterfly Bicyclus anynana

Environmentally induced phenotypic plasticity is common in nature. Hormones, affecting multiple traits and signaling to a variety of distant target tissues, provide a mechanistic link between environments, genes and trait expression, and may therefore well be involved in the regulation phenotypic plasticity. Here, we investigate whether in the tropical butterfly Bicyclus anynana temperature-mediated plasticity in egg size and number, with fewer but larger eggs produced at lower temperatures and vice versa, is under control of juvenile hormone, and whether different temperatures cause differences in egg composition. Female B. anynana butterflies showed the expected response to temperature, however, we found no evidence for an involvement of juvenile hormone. Neither haemolymph JH II and JH III titres nor vitellogenin levels differed across temperatures. The smaller eggs produced at the higher temperature contained relatively higher amounts of water, free carbohydrates and proteins, but relatively lower amounts of lipids. While these smaller eggs had a lower absolute energy content, total reproductive investment was higher at the higher temperature (due to a higher fecundity). Overall, our study indicates that temperature-mediated plasticity in reproduction in B. anynana is mechanistically related to a biophysical model, with oocyte production (differentiation) and oocyte growth (vitellogenesis) having differential temperature sensitivities.

Lipid mobilization and locomotor stimulation in Gryllus bimaculatus by topically applied adipokinetic hormone

Abstract.  Walking activity of 3‐day‐old adult female Gryllus bimaculatus (de Geer) (Ensifera, Gryllidae) was measured over 24 h. A high level of locomotor activity during the scotophase was found, which was two‐ to three‐fold higher than that during the photophase. The titre of lipid in the haemolymph was relatively low 2 h after lights on, increased significantly 2 h after lights off, although, 2 h after lights on in the next photophase, the lipid titre had decreased to the basal level. Topical application of homologous Grybi‐adipokinetic hormone (AKH) (100 pmol in 20% 2‐propanol) led to a significant increase in haemolymph lipids, comparable with the maximal increase caused by injection of AKH (3 pmol in water). Topical application of AKH also stimulated locomotor activity in crickets (maximal stimulation 1.8‐fold with 100 pmol Grybi‐AKH). The results suggest that AKH penetrates the cuticle quickly. It is assumed that AKH stimulates locomotory activity at least in part via the increase of haemolymph lipid titres; however, the stimulation of locomotor activity via a direct neuromodulatory effect of AKH cannot be excluded.

Egg composition and reproductive investment in aphidophagous ladybird beetles (Coccinellidae: Coccinellini): egg development and interspecific variation

Abstract Most studies of insect reproductive allocation concentrate on propagule size and number and very few consider egg composition, which is likely to be equally important. In the present study, data are provided on changes in egg lipid, glycogen, free carbohydrate and protein during embryonic development of the aphidophagous ladybird Adalia bipunctata (L.) and the compositions of A. bipunctata, Adalia decempunctata and Anisosticta novemdecimpunctata eggs are compared. In A. bipunctata, egg mass, lipid and glycogen decline strongly during development and egg protein declines more weakly. Free carbohydrate declines early in egg development and increases at egg hatching. Lipid is energetically the most important developmental fuel, although approximately half of the initial egg lipid remains in the neonate larva. Across the three species, energy per unit egg mass is lowest in the least specialized species, A. bipunctata, which also has the largest eggs, and is highest in the most specialized, An. novemdecimpunctata, which has the smallest eggs. Two possible explanations for the observed pattern are discussed: (i) species laying smaller eggs may incur higher developmental costs per unit mass than species laying larger eggs and (ii) more specialized species, which reproduce at lower aphid densities, may provision neonate larvae better to facilitate location and capture of aphids.