Locust phase polyphenism: Does epigenetic precede endocrine regulation?

The morphological, physiological and behavioural differences between solitarious and gregarious desert locusts are so pronounced that one could easily mistake the two phases as belonging to different species, if one has no knowledge of the phenomenon of phenotypic plasticity. A number of phase-specific features are hormonally controlled. Juvenile hormone promotes several solitarious features, the green cuticular colour being the most obvious one. The neuropeptide corazonin elicits the dark cuticular colour that is typical for the gregarious phase, as well as particular gregarious behavioural characteristics. However, it had to be concluded, for multiple reasons, that the endocrine system is not the primary phase-determining system. Our observation that longevity gets imprinted in very early life by crowding of the young hatchlings, and that it cannot be changed thereafter, made us consider the possibility that, perhaps, epigenetic control of gene expression might be, if not the missing, a primary phase-determining mechanism. Imprinting is likely to involve DNA methylation and histone modification. Analysis of a Schistocerca EST database of nervous tissue identified the presence of several candidate genes that may be involved in epigenetic control, including two DNA methyltransferases (Dnmts). Dnmt1 and Dnmt2 are phase-specifically expressed in certain tissues. In the metathoracic ganglion, important in the serotonin pathway for sensing mechanostimulation, their expression is clearly affected by crowding. Our data urge for reconsidering the role of the endocrine system as being sandwiched in between genetics and epigenetics, involving complementary modes of action.

Development of a real-time PCR assay for measurement of yellow protein mRNA transcription in the desert locust Schistocerca gregaria: a basis for isolation of a peptidergic regulatory factor.

A major unresolved issue in insect endocrinology concerns the question of whether or not insects have sex hormones. Conclusive evidence in favor of the presence of such hormones awaits the establishment of appropriate bioassays in males. The cuticle of sexually mature males of the desert locust Schistocerca gregaria turns yellow in gregarious conditions only. Neither females nor isolated males ever turn yellow. The yellowing is due to the deposition in the cuticle of a male-specific Yellow Protein (YP), of which the amino acid sequence is known. In this paper, we describe the partial cloning of the cDNA encoding this Yellow Protein. The tissue distribution and temporal expression of the YP-mRNA is studied in detail using RT-PCR. Furthermore, an RT-PCR based bioassay was developed, which may serve as a reliable tool to help identify the hormones controlling the yellowing process. In addition to juvenile hormone, we have shown that a factor present in the brain-corpora cardiaca is involved in the yellow coloration, as injection of an extract induces the expression of YP-mRNA in isolated gregarious males.

Neuroparsin transcripts as molecular markers in the process of desert locust (Schistocerca gregaria) phase transition.

Desert locust swarms occasionally cause severe ecological and economic damage, particularly in countries of northwest Africa. However, the physiological mechanisms underlying locust phase transition, the switch of the solitarious to the gregarious phase, remain elusive. Therefore, identification of molecular changes linked to this phenomenon represents a primary requirement to start unraveling this enigma. The present paper provides novel information on phase-related molecular markers for locust phase transition. We present a detailed quantitative real-time RT-PCR analysis of two distinct neuroparsin precursor transcripts (Scg-NPP3 and Scg-NPP4) in the brain and in abdominal tissues of gregarious and solitarious desert locusts (Schistocerca gregaria). Our data reveal different temporal changes of these transcripts in the fat body during the adult stage of both phases. We, hereby, present novel scientific evidence for a phase-dependent regulation of these particular peptide hormone encoding transcripts and assign them as possible molecular markers in the process of locust phase transition.

The instantly released Drosophila immune proteome is infection-specific.

In this study, we analyzed the hemolymph proteome of Drosophila third instar larvae, which were induced with a suspension of Gram-positive bacteria or yeast. Profiling of the hemolymph proteins of infected versus non-infected larvae was performed by two-dimensional difference gel electrophoresis. Infection with Micrococcus luteus or Saccharomyces cerevisiae induced, respectively, 20 and 19 differential protein spots. The majority of the spots are specifically regulated by one pathogen, whereas only a few spots correspond to proteins altered in all cases of challenging (including after challenge with lipopolysaccharides). All of the upregulated proteins can be assigned to specific aspects of the immune system, as they did not increase in the hemolymph of sterile pricked larvae. Next to known immune proteins, unannotated proteins were identified such as CG4306 protein, which has homologues with unknown function in all metazoan genome databases available today.

Neuropeptidomics of the grey flesh fly, Neobellieria bullata.

A peptidomics approach was applied to determine the peptides in the larval central nervous system of the grey flesh fly, Neobellieria bullata. Fractions obtained by high performance liquid chromatography were analysed by MALDI-TOF and ESI-Q-TOF mass spectrometry. This provided biochemical evidence for the presence of 18 neuropeptides, 11 of which were novel Neobellieria peptides. Most prominently present were the FMRFamide-related peptides: 7 FMRFamides, 1 FIRFamide, and Neb-myosuppressin. The three putative capa-gene products Neb-pyrokinin and the periviscerokinins Neb-PVK-1 and -2 were detected, as well as another pyrokinin. This Neb-PK-2 was also present in the ring gland along with corazonin, Neb-myosuppressin, and Neb-AKH-GK, an intermediate processing product of the adipokinetic hormone. Furthermore, the central nervous system contained Neb-LFamide, proctolin, and FDFHTVamide, designated as Neb-TVamide. With this study, we considerably increased our knowledge of the neuropeptidome of the pest fly N. bullata, which is an important insect model for physiological research.