Jurgen Huybrechts

Genomics, transcriptomics, and peptidomics of Daphnia pulex neuropeptides and protein hormones.

We report 43 novel genes in the water flea Daphnia pulex encoding 73 predicted neuropeptide and protein hormones as partly confirmed by RT-PCR. MALDI-TOF mass spectrometry identified 40 neuropeptides by mass matches and 30 neuropeptides by fragmentation sequencing. Single genes encode adipokinetic hormone, allatostatin-A, allatostatin-B, allatotropin, Ala(7)-CCAP, CCHamide, Arg(7)-corazonin, DENamides, CRF-like (DH52) and calcitonin-like (DH31) diuretic hormones, two ecdysis-triggering hormones, two FIRFamides, one insulin, two alternative splice forms of ion transport peptide (ITP), myosuppressin, neuroparsin, two neuropeptide-F splice forms, three periviscerokinins (but no pyrokinins), pigment dispersing hormone, proctolin, Met(4)-proctolin, short neuropeptide-F, three RYamides, SIFamide, two sulfakinins, and three tachykinins. There are two genes for a preprohormone containing orcomyotropin-like peptides and orcokinins, two genes for N-terminally elongated ITPs, two genes (clustered) for eclosion hormones, two genes (clustered) for bursicons alpha, beta, and two genes (clustered) for glycoproteins GPA2, GPB5, three genes for different allatostatins-C (two of them clustered) and three genes for IGF-related peptides. Detailed comparisons of genes or their products with those from insects and decapod crustaceans revealed that the D. pulex peptides are often closer related to their insect than to their decapod crustacean homologues, confirming that branchiopods, to which Daphnia belongs, are the ancestor group of insects.

Neuropeptidomic analysis of the brain and thoracic ganglion from the Jonah crab, Cancer borealis

Mass spectrometric methods were applied to determine the peptidome of the brain and thoracic ganglion of the Jonah crab (Cancer borealis). Fractions obtained by high performance liquid chromatography were characterized using MALDI-TOF MS and ESI-Q-TOF MS/MS. In total, 28 peptides were identified within the molecular mass range 750-3000Da. Comparison of the molecular masses obtained with MALDI-TOF MS with the calculated molecular masses of known crustacean peptides revealed the presence of at least nine allatostatins, three orcokinin precursor derived peptides, namely FDAFTTGFGHS, [Ala(13)]-orcokinin, and [Val(13)]-orcokinin, and two kinins, a tachykinin-related peptide and four FMRFamide-related peptides. Eight other peptides were de novo sequenced by collision induced dissociation on the Q-TOF system and yielded AYNRSFLRFamide, PELDHVFLRFamide or EPLDHVFLRFamide, APQRNFLRFamide, LNPFLRFamide, DVRTPALRLRFamide, and LRNLRFamide, which belong to the FMRFamide related peptide family, as well as NFDEIDRSGFA and NFDEIDRSSFGFV, which display high sequence similarity to peptide sequences within the orcokinin precursor of Orconectes limosus. Our paper is the first (neuro)peptidomic analysis of the crustacean nervous system.

Transcriptome analysis of the desert locust central nervous system: production and annotation of a Schistocerca gregaria EST database.

Background The desert locust (Schistocerca gregaria) displays a fascinating type of phenotypic plasticity, designated as ‘phase polyphenism’. Depending on environmental conditions, one genome can be translated into two highly divergent phenotypes, termed the solitarious and gregarious (swarming) phase. Although many of the underlying molecular events remain elusive, the central nervous system (CNS) is expected to play a crucial role in the phase transition process. Locusts have also proven to be interesting model organisms in a physiological and neurobiological research context. However, molecular studies in locusts are hampered by the fact that genome/transcriptome sequence information available for this branch of insects is still limited. Methodology We have generated 34,672 raw expressed sequence tags (EST) from the CNS of desert locusts in both phases. These ESTs were assembled in 12,709 unique transcript sequences and nearly 4,000 sequences were functionally annotated. Moreover, the obtained S. gregaria EST information is highly complementary to the existing orthopteran transcriptomic data. Since many novel transcripts encode neuronal signaling and signal transduction components, this paper includes an overview of these sequences. Furthermore, several transcripts being differentially represented in solitarious and gregarious locusts were retrieved from this EST database. The findings highlight the involvement of the CNS in the phase transition process and indicate that this novel annotated database may also add to the emerging knowledge of concomitant neuronal signaling and neuroplasticity events. Conclusions In summary, we met the need for novel sequence data from desert locust CNS. To our knowledge, we hereby also present the first insect EST database that is derived from the complete CNS. The obtained S. gregaria EST data constitute an important new source of information that will be instrumental in further unraveling the molecular principles of phase polyphenism, in further establishing locusts as valuable research model organisms and in molecular evolutionary and comparative entomology.

Neuropeptide and neurohormone precursors in the pea aphid, Acyrthosiphon pisum.

Aphids respond to environmental changes by developing alternative phenotypes with differing reproductive modes. Parthenogenetic reproduction occurs in spring and summer, whereas decreasing day lengths in autumn provoke the production of sexual forms. Changing environmental signals are relayed by brain neuroendocrine signals to the ovarioles. We combined bioinformatic analyses with brain peptidomics and cDNA analyses to establish a catalogue of pea aphid neuropeptides and neurohormones. 42 genes encoding neuropeptides and neurohormones were identified, of which several were supported by expressed sequence tags and/or peptide mass analyses. Interesting features of the pea aphid peptidome are the absence of genes coding for corazonin, vasopressin and sulfakinin and the presence of 10 different genes coding insulin related peptides, one of which appears to be very abundantly expressed.

Peptidomics: The integrated approach of MS, hyphenated techniques and bioinformatics for neuropeptide analysis

MS is currently one of the most important analytical techniques in biological and medical research. ESI and MALDI launched the field of MS into biology. The performance of mass spectrometers increased tremendously over the past decades. Other technological advances increased the analytical power of biological MS even more. First, the advent of the genome projects allowed an automated analysis of mass spectrometric data. Second, improved separation techniques, like nanoscale HPLC, are essential for MS analysis of biomolecules. The recent progress in bioinformatics is the third factor that accelerated the biochemical analysis of macromolecules. The first part of this review will introduce the basics of these techniques. The field that integrates all these techniques to identify endogenous peptides is called peptidomics and will be discussed in the last section. This integrated approach aims at identifying all the present peptides in a cell, organ or organism (the peptidome). Today, peptidomics is used by several fields of research. Special emphasis will be given to the identification of neuropeptides, a class of short proteins that fulfil several important intercellular signalling functions in every animal. MS imaging techniques and biomarker discovery will also be discussed briefly.

Annotation of novel neuropeptide precursors in the migratory locust based on transcript screening of a public EST database and mass spectrometry

BackgroundFor holometabolous insects there has been an explosion of proteomic and peptidomic information thanks to large genome sequencing projects. Heterometabolous insects, although comprising many important species, have been far less studied. The migratory locust Locusta migratoria, a heterometabolous insect, is one of the most infamous agricultural pests. They undergo a well-known and profound phase transition from the relatively harmless solitary form to a ferocious gregarious form. The underlying regulatory mechanisms of this phase transition are not fully understood, but it is undoubtedly that neuropeptides are involved. However, neuropeptide research in locusts is hampered by the absence of genomic information.ResultsRecently, EST (Expressed Sequence Tag) databases from Locusta migratoria were constructed. Using bioinformatical tools, we searched these EST databases specifically for neuropeptide precursors. Based on known locust neuropeptide sequences, we confirmed the sequence of several previously identified neuropeptide precursors (i.e. pacifastin-related peptides), which consolidated our method. In addition, we found two novel neuroparsin precursors and annotated the hitherto unknown tachykinin precursor. Besides one of the known tachykinin peptides, this EST contained an additional tachykinin-like sequence. Using neuropeptide precursors from Drosophila melanogaster as a query, we succeeded in annotating the Locusta neuropeptide F, allatostatin-C and ecdysis-triggering hormone precursor, which until now had not been identified in locusts or in any other heterometabolous insect. For the tachykinin precursor, the ecdysis-triggering hormone precursor and the allatostatin-C precursor, translation of the predicted neuropeptides in neural tissues was confirmed with mass spectrometric techniques.ConclusionIn this study we describe the annotation of 6 novel neuropeptide precursors and the neuropeptides they encode from the migratory locust, Locusta migratoria. By combining the manual annotation of neuropeptides with experimental evidence provided by mass spectrometry, we demonstrate that the genes are not only transcribed but also translated into precursor proteins. In addition, we show which neuropeptides are cleaved from these precursor proteins and how they are post-translationally modified.

Mass spectrometric analysis of the perisympathetic organs in locusts: identification of novel periviscerokinins.

A mass spectrometric analysis carried out to determine the peptidome of the abdominal perisympathetic organs in the locust species Locusta migratoria and Schistocerca gregaria yielded a number of predominant ion peaks, among which are Lom-PVK (AAGLFQFPRVamide) and Scg-MT-2 (TSSLFPHPRLamide). In addition, three novel peptides were identified: Lom-PVK-2 (identical in Schistocerca): GLLAFPRVamide, Lom-PVK-3: DGGEPAAPLWFGPRVamide, and Scg-PVK-3: DGAETPGAAASLWFGPRVamide. An extensive mass spectrometric study of the central nervous system showed that the periviscerokinins (-PRVamides) and Scg-MT-2 (-FXXPRLamide) are restricted to the abdominal ganglia and their perisympathetic organs, while the pyrokinins (-FXPRLamides) are present only in the brain-retrocerebral complex. Sequence comparison with the Drosophila genes supports a conserved gene structure whereby a capability-like gene encodes the periviscerokinins that are expressed in the abdominal ganglia and stored in the perisympathetic organs, while a hugin-like gene encodes the pyrokinins that are expressed in the head ganglia and stored in the retrocerebral complex.

SIFamide illustrates the rapid evolution in Arthropod neuropeptide research

This review is focussed on SIFamide. This neuropeptide was discovered as a result of an extensive purification process, typical for 20th century physiology, of an extract of 350,000 flesh flies. Our knowledge of SIFamide greatly expanded since the first publication in 1996. Describing the minor and major findings on this peptide is our lead to summarise a number of innovations that recently became common in research on Arthropods. Mass spectrometry, nanoLC, whole mount immunocytochemistry, genome sequencing, deorphanizing receptors and functional gene knock downs are aspects that dramatically improved and changed peptide research. Some of the techniques mentioned in this review were of course applied before 1996, but they were not widespread. Although the focus of the review is on insects we incorporated the data of SIFamide in Crustaceans as well. SIFamide illustrates that crustaceans and insects might have more in common than was previously anticipated. Today, six isoforms of SIFamide are discovered in many crustaceans, several insects and a tick. The sequence of SIFamide is extremely conserved among these species. Deorphanizing its receptor in Drosophila, learned that both the ligand and receptor are impressively conserved, pointing at a crucial function. Immunohistochemistry and mass spectrometry data reveal that SIFamide is present in the crustacean brain and gut, but restricted to four neurons in the insect pars intercerebralis. The immunoreactive patterns in the brain refer to a neuromodulatory role in combining visual, tactile and olfactory input. Eventually, targeted cell ablation and RNAi revealed that SIFamide modulates sexual behaviour in fruit flies.

Purification and characterization of an insulin-related peptide in the desert locust, Schistocerca gregaria: immunolocalization, cDNA cloning, transcript profiling and interaction with neuroparsin

Members of the insulin superfamily are not restricted to vertebrates, but have also been identified in invertebrate species. In the current report, we present the characterization of Scg-insulin-related peptide (IRP), an insulin-related peptide in the desert locust, Schistocerca gregaria. This peptide was isolated from corpora cardiaca (CC) extracts by means of a high-performance liquid chromatography (HPLC)-based purification strategy. Subsequent cloning and sequencing of the corresponding cDNA revealed that the encoded Scg-IRP precursor displays the structural organization that is typical for members of the insulin superfamily. Moreover, immunocytochemistry on brain tissue sections demonstrated the presence of Scg-IRP in median neurosecretory cells of the pars intercerebralis and their projections towards the storage part of the CC. Quantitative real-time RT-PCR studies revealed the presence of Scg-IRP transcripts in a variety of tissues, including nervous tissue and fat body. Furthermore, these transcripts showed a tissue- and phase-dependent, temporal regulation during the reproductive cycle of adult males and females. Finally, we demonstrated that Scg-IRP interacts in vitro with a recombinant neuroparsin, a locust protein displaying sequence similarity with vertebrate IGF binding proteins.

New insights in Adipokinetic Hormone (AKH) precursor processing in Locusta migratoria obtained by capillary liquid chromatography-tandem mass spectrometry

After translation, the AKH I and AKH II precursors form three dimeric constructs prior to further processing into the respective AKHs and three dimeric Adipokinetic Hormone Precursor Related Peptides or APRPs (two homodimers and one heterodimer). By capillary liquid chromatography-tandem mass spectrometry we demonstrate that the APRPs in Locusta migratoria are further processed to form two smaller neuropeptides: DAADFADPYSFL (residue 36 to 47 of the AKH I precursor) and YADPNADPMAFL (residue 34 to 45 of the AKH II precursor). The peptides are designated as Adipokinetic Hormone Joining Peptide 1 (AKH-JP I) and 2 (AKH-JP II) respectively. Within the AKH I and AKH II precursor molecules, the classic KK and RR processing sites separate the AKH-JPs from the AKH I and II respectively. At the carboxyterminus, both AKH-JP I and II are flanked by Tyr-Arg, a cleaving site not described before. Such an unusual cleavage site suggests the presence, in the corpora cardiaca, of specific convertases. The AKH-JP-II does not stimulate lipid release from the fat body nor does it stimulate glycogen phosphorylase activity, both key functions of AKH.