corazonin-protein--insect and Albinism

Albinism is caused by mutations in the genes involved in melanin production. Albino nymphs of Locusta migratoria and Schistocerca gregaria reared under crowded conditions are uniformly creamy-white in color. However, nothing is known about the molecular mechanisms underlying this phenomenon in locusts. The albino strain of L. migratoria is known to lack the dark-color-inducing neuropeptide corazonin (Crz). In this study, we report that this albino strain has a 10-base-pair deletion in the gene LmCRZ, which encodes Crz. This mutation was found to cause a frame-shift, resulting in a null mutation in Crz. On the other hand, the albino strain of S. gregaria is known to have an intact Crz. This strain was found to possess a single-nucleotide substitution in the middle of the Crz receptor-encoding gene, SgCRZR, which caused a nonsense mutation, resulting in a truncated receptor. Silencing of SgCRZR in wild-type S. gregaria nymphs greatly reduced the area and intensity of their black patterning, suggesting that the functional defect of SgCRZR likely causes the albinism. The expression level of SgCRZR in the albino S. gregaria was comparable to that in the wild type. Unlike the wild type, the albino strain of this locust did not show a phase-dependent shift in a morphometric trait controlled by Crz. From these results, we conclude that the mutations in LmCRZ and SgCRZR are responsible for the albinism in L. migratoria and S. gregaria, respectively, indicating that the two types of albinism are caused by different genetic defects in the same Crz signaling pathway.

Topics: Albinism; Animal Migration; Animals; Desert Climate; Grasshoppers; Insect Proteins; Locusta migratoria; Mutant Proteins; Mutation; Neuropeptides; Pigmentation; Receptors, Neuropeptide; Signal Transduction

Upon realizing that for drug delivery in the body, lipidization is a technique used in the pharmaceutical industry, we took in consideration that corazonin melanizes the cuticle of albino Locusta migratoria only when injected in an emulsion in oil, not when applied in a watery solution. In this study, we investigate the possibility for oral uptake of corazonin dispersed in oil, and validated the activity by a melanization assay. Not only was it active, it also induced red cuticular coloration in some animals, and it was also unexpectedly lethal for nymphs, but not for adults. These results necessitate the revision of the potential of (some) peptides for insect control. Also, they suggest practical recommendations for the application of other peptides in physiological assays where oil could be used as a simple slow release formula.

Topics: Administration, Oral; Albinism; Animals; Emulsions; Female; Hydrophobic and Hydrophilic Interactions; Insect Control; Insect Proteins; Locusta migratoria; Male; Neuropeptides; Nymph; Pigmentation; Plant Oils

In the 11-residue long dark-color-inducing neurohormone (DCIN = [His7]-corazonin), of locusts, from residue 2 to residue 11, one amino acid at each time was substituted by D-phenylalanine (D-Phe). The dark-color-inducing effect of these peptides was investigated in comparison with unaltered DCIN by a bioassay based on nymphs of a DCIN-deficient albino mutant of the migratory locust, Locusta migratoria. Substitution of any single amino acid by D-Phe always reduced the activity, but did not abolish it completely. Maximum inactivation was obtained after substitution of Gln4, Ser6, or Trp9. The latter two residues are within the partial sequence -Ser-Xxx-Gly-Trp- (Xxx = His in theDCIN) that seems to be important for the dark-color-inducing activity, as found also in another study (Insect Biochem. Mol. Biol.32, 2002, 909). GIn4, however, is outside of this partial sequence.Minimal, although still considerable, inactivation occurred after substitution of Gly8, Phe3, or Asn11, despite the fact that Gly8 is within the -Ser-Xxx-Gly-Trp- partial sequence. In conclusion, no single active core was found, indicating that the whole sequence of the DCIN is necessary to induce maximum darkening effect. No difference was found in the activity of the peptides in which Gly8was substituted by D-Phe or by L-Phe. Therefore the -Ser-Xxx-Gly-Trp- partial sequence does not seem to be stabilized by a type II beta-turn. Nevertheless, existence of another kind of turn that includes this partial sequence is feasible. A single unsuccessful attempt was made to discover an antagonist to the DCIN.

Topics: Albinism; Amino Acid Substitution; Animals; Biological Assay; Color; Dose-Response Relationship, Drug; Grasshoppers; Insect Hormones; Insect Proteins; Neuropeptides; Neurotransmitter Agents; Nymph; Peptides; Phenylalanine; Structure-Activity Relationship