Pigment-dispersing factor is involved in photoperiodic control of reproduction in the brown-winged green bug, Plautia stali.

Animals in temperate regions breed in the appropriate season by sensing seasonal changes through photoperiodism. Many studies suggest the involvement of a circadian clock system in the photoperiodic regulation of reproduction. Pigment-dispersing factor (PDF) is a known brain neuropeptide involved in the circadian control in various insects. Here, we investigated the localization and projection of PDF neurons in the brain and their involvement in the photoperiodic control of reproduction in the females of the brown-winged green bug, Plautia stali. Immunohistochemical analyses revealed a dense cluster of PDF-immunoreactive cells localized in the proximal medulla of the optic lobe, which corresponded to the cluster known as PDFMe cells. PDF-immunoreactive cells projected their fibers to the lamina through the medulla surface. PDF-immunoreactive fibers were also found in the protocerebrum and seemed to connect both PDF cell bodies in the optic lobes. RNA interference-mediated knockdown of pdf inhibited oviposition arrest induced by the transfer from long- to short-day conditions. Additionally, the knockdown of pdf delayed oviposition onset after the change from short- to long-day conditions. In conclusion, the study results indicate that PDF is locally expressed in a cell cluster at the proximal medulla and involved in the photoperiodic control of reproduction in P. stali females.

Juvenile hormone III skipped bisepoxide is widespread in true bugs (Hemiptera: Heteroptera).

Juvenile hormone (JH) plays important roles in almost every aspect of insect development and reproduction. JHs are a group of acyclic sesquiterpenoids, and their farnesol backbone has been chemically modified to generate a homologous series of hormones in some insect lineages. JH III (methyl farnesoate, 10,11-epoxide) is the most common JH in insects, but Lepidoptera (butterflies and moths) and 'higher' Diptera (suborder: Brachycera; flies) have developed their own unique JHs. Although JH was first proposed in the hemipteran suborder Heteroptera (true bugs), the chemical identity of the heteropteran JH was only recently determined. Furthermore, recent studies revealed the presence of a novel JH, JH III skipped bisepoxide (JHSB3), in some heteropterans, but its taxonomic distribution remains largely unknown. In the present study, we investigated JHSB3 production in 31 heteropteran species, covering almost all heteropteran lineages, through ultra-performance liquid chromatography coupled with tandem mass spectrometry. We found that all of the focal species produced JHSB3, indicating that JHSB3 is widespread in heteropteran bugs and the evolutionary occurrence of JHSB3 ascends to the common ancestor of Heteroptera.

Juvenile hormone III skipped bisepoxide, not its stereoisomers, as a juvenile hormone of the bean bug Riptortus pedestris.

Juvenile hormone (JH) plays a pivotal role in many aspects of insect physiology. Although its presence was first reported in a blood-sucking bug belonging to the suborder Heteroptera (true bugs), JH species in the group has long been controversial. Although some recent studies proposed a putative JH molecular species in several Heteropteran species, it is not conclusive because physicochemical analyses were insufficient in most cases. Here, we studied this issue with an ultraperformance liquid chromatography-tandem mass spectrometer (UPLC-MS/MS) equipped with C18 and chiral columns in the bean bug Riptortus pedestris (Heteroptera, Alydidae), in which the JH species has long been controversial. Although a recent study describes JHSB3 as the major JH of this species, that finding was not conclusive because its chirality has not been clarified. In the present study, we detected methyl (2R,3S,10R)-2,3;10,11-bisepoxyfarnesoate, commonly named juvenile hormone III skipped bisepoxide (JHSB3), in the culture media of the corpora cardiaca-corpus allatum (CC-CA) complex and in the hemolymph of this species by a chiral ultraperformance liquid chromatography- tandem mass spectrometer (UPLC-MS/MS). Other JHSB3 stereoisomers were not detected. Topical application of JHSB3 effectively averted diapause. These results indicate that JHSB3 is the major JH of R. pedestris. The present study further revealed that JHSB3 and its (2R,3S,10S) isomer are more potent than (2S,3R,10R) and (2S,3R,10S) isomers, which suggests that there is a significance to the configuration of the 2,3-epoxide moiety in JH action. We further found a supplemental significance to the configuration of the 10-position.

Burkholderia gut symbiont modulates titer of specific juvenile hormone in the bean bug Riptortus pedestris.

Recent studies have provided molecular evidence that gut symbiotic bacteria modulate host insect development, fitness and reproduction. However, the molecular mechanisms through which gut symbionts regulate these aspects of host physiology remain elusive. To address these questions, we prepared two different Riptortus-Burkholderia insect models, Burkholderia gut symbiont-colonized (Sym) Riptortus pedestris insects and gut symbiont-noncolonized (Apo) insects. Upon LC-MS analyses, juvenile hormone III skipped bisepoxide (JHSB3) was newly identified from Riptortus Apo- and Sym-female and male adults' insect hemolymph and JHSB3 titer in the Apo- and Sym-female insects were measured because JH is important for regulating reproduction in adult insects. The JHSB3 titer in the Sym-females were consistently higher compared to those of Apo-females. Since previous studies reported that Riptortus hexamerin-α and vitellogenin proteins were upregulated by the topical abdominal application of a JH-analog, chemically synthesized JHSB3 was administered to Apo-females. As expected, the hexamerin-α and vitellogenin proteins were dramatically increased in the hemolymph of JHSB3-treated Apo-females, resulting in increased egg production compared to that in Sym-females. Taken together, these results demonstrate that colonization of Burkholderia gut symbiont in the host insect stimulates biosynthesis of the heteroptera-specific JHSB3, leading to larger number of eggs produced and enhanced fitness in Riptortus host insects.

Identification of allatostatins in the brown-winged green bug Plautia stali.

Juvenile hormone (JH) biosynthesis is inhibited under short-day conditions in the brown-winged green bug Plautia stali. We investigated allatostatic molecules in the brain of P. stali. Methanol brain extracts strongly inhibited JH biosynthesis. The allatostatic activities of the brain extracts were heat stable but gently suppressed by trypsin treatment, indicating that the allatostatic molecules were peptides. Grybi-MIP1, found in Gryllus bimaculatus as an allatostatic molecule, inhibited JH biosynthesis in P. stali. In contrast, peptides such as Dippu-AST2, 8, and 9, found in Diploptera punctata, did not affect JH biosynthesis in P. stali. We found a cDNA sequence encoding a peptide precursor of myoinhibitory peptides (MIPs), which we named Plast-MIP. Three synthetic peptides, AWKDLSKAW-NH2 (Plast-MIP1), GWSDLQSAGW-NH2 (Plast-MIP5), and AADWGSFRGSW-NH2 (Plast-MIP8), deduced from the precursor sequence, showed clear inhibition of JH biosynthesis in P. stali. Analysis by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and tandem mass spectrometry showed that Plast-MIP8 resides in the brain. Expression of the Plast-MIP mRNA precursor was detected in the brain of insects reared under short- and long-day conditions. These results suggest that Plast-MIP is an allatostatic molecule and that MIPs are synthesized irrespective of photoperiod. To our knowledge, this is the first study to identify Plast-MIP as a functional allatostatin in hemipteran insects.

Characterization of two adenine nucleotide translocase paralogues in the stink bug, Plautia stali.

Adenine nucleotide translocase (ANT) is a nuclear-coded mitochondrial protein that exchanges ATP for ADP across the mitochondrial inner membrane. Most organisms possess several ANT paralogues, and functional differences among these paralogues remain largely unknown. In the present study, we identified ANT paralogue genes in hemipteran species: the stink bug, bean bug, pea aphid, and Japanese mealybug. The ANT paralogues of the stink bug, Plautia stali, are encoded by two genes, PsANTI1 and PsANTI2. PsANTI1 was constantly expressed at all developmental stages and in all tissues analyzed. In contrast, the expression levels of PsANTI2 were undetectable in first instar nymphs and adult antennae. Gene silencing of each paralogue in P. stali revealed that PsANTI1 plays an important role in homeostasis, whereas the depletion of PsANTI2 failed to result in lethality. Thus, we concluded that PsANTI1 is a good target gene for developing novel pesticides.

Biological activities of juvenile hormone III skipped bisepoxide in last instar nymphs and adults of a stink bug, Plautia stali.

Juvenile hormone III skipped bisepoxide (JHSB(3)), methyl (2R,3S,10R)-2,3;10,11-bisepoxyfarnesoate was recently determined as a novel juvenile hormone (JH) in a stink bug, Plautia stali. To further confirm the biological function of JHSB(3) in this insect, its juvenilizing, reproduction-stimulating and diapause-terminating activities and the presence in the hemolymph were examined. Topical application of JHSB(3) to last instar nymphs inhibited their metamorphosis in a dose-dependent fashion. In allatectomized and diapausing adults, JHSB(3) application exerted stimulatory effects on the development of ovaries and ectadenia in females and males, respectively. JHSB(3) was detected from the hemolymph of reproductively active females by gas chromatography-mass spectrometry analysis while its titer in the hemolymph collected from diapausing adults was too low to be detected. These results demonstrated that JHSB(3) has biological function as a JH in P. stali. Topical application of JHSB(3), its stereoisomers and 10R-JH III also indicated that compounds with the 2R,3S-configuration were more potent than those with the 2S,3R-configuration and 2,3-double bond.

Structure determination of a new juvenile hormone from a heteropteran insect.

The structure of the juvenile hormone (JH) in the suborder Heteroptera, order Hemiptera, has been known for a very long time to be different from the JH of other orders, but the structure has been a matter of controversy. The structure was first elucidated by an unprecedented approach involving the screening of a JH molecular library. The novel Heteroptera-specific JH (JHSB(3)) is a new category of JH that is featured by the skipped bisepoxide structure.