Pr-lynx1, a modulator of nicotinic acetylcholine receptors in the insect.

Insect nicotinic acetylcholine receptors (nAChRs) are targets for insecticides. Despite the importance of the nAChR as a major target for insecticide action, modulators of nAChRs in insects remain unidentified. Here we describe the cloning and identification of a nAChR modulator gene in an insect. This gene was isolated by searching the firefly Pyrocoelia rufa cDNA library, and the gene itself encodes a protein 120 amino acids in length, named Pr-lynx1. Pr-lynx1 shares all the features, including a cysteine-rich consensus motif and common gene structure, of the Ly-6/neurotoxin superfamily. The recombinant Pr-lynx1, which is expressed as a 12-kDa polypeptide in baculovirus-infected insect Sf9 cells, is normally present at the cell surface as a GPI-anchored protein. Northern and Western blot analyses revealed that Pr-lynx1 is expressed in various tissues, such as the ganglion, brain, mandibular muscle, proventriculus, leg muscle, and epidermis. This expression pattern is similar to the distribution of nAChRs as assayed by alpha3 nAChR immunoreactivity. Co-expression of Pr-lynx1 in Xenopus oocytes expressing alpha3beta4 nAChRs results in an increase in acetylcholine-evoked macroscopic currents, indicating a functional role of Pr-lynx1 as a protein modulator for nAChRs. This study on Pr-lynx1 is the first report of a modulator of nAChRs in an insect species.

Genomic structure of the luciferase gene and phylogenetic analysis in the Hotaria-group fireflies.

The luminescent fireflies have species specific flash patterns, being recognized as sexual communication. The luciferase gene is the sole enzyme responsible for bioluminescence. We describe here the complete nucleotide sequence and the exon-intron structure of the luciferase gene of the Hotaria-group fireflies, H. unmunsana, H. papariensis and H. tsushimana. The luciferase gene of the Hotaria-group firefly including the known H. parvula spans 1950 bp and consisted of six introns and seven exons coding for 548 amino acid residues, suggesting highly conserved structure among the Hotaria-group fireflies. Although only one luciferase gene was cloned from H. papariensis, each of the two sequences of the gene was found in H. unmunsana (U1 and Uc) and H. tsushimana (T1 and T2). The amino acid sequence divergence among H. unmunsana, H. papariensis, and H. tsushimana only ranged from zero to three amino acid residues, but H. parvula differed by 10-11 amino acid residues from the other Hotaria-group fireflies, suggesting a divergent relationship of this species. Phylogenetic analysis using the deduced amino acid sequences of the luciferase gene resulted in a monophyletic group in the Hotaria excluding H. parvula, suggesting a close relationship among H. unmunsana, H. papariensis and H. tsushimana. Additionally, we also analyzed the mitochondrial cytochrome oxidase I (COI) gene of the Hotaria-group fireflies. The deduced amino acid sequence of the COI gene of H. unmunsana was identical to that of H. papariensis and H. tsushimana, but different by three positions from H. parvula. In terms of nucleotide sequences of the COI gene, intraspecific sequence divergence was sometimes larger than interspecies level, and phylogenetic analysis placed the three species into monophyletic groups unresolved among them, but excluded H. parvula. In conclusion, our results suggest that H. unmunsana, H. papariensis and H. tsushimana are very closely related or might be an identical species, at least based on the luciferase and COI genes.

Mitochondrial DNA sequence-based population genetic structure of the firefly, Pyrocoelia rufa (Coleoptera: Lampyridae).

The genetic divergence, population genetic structure, and possible speciation of the Korean firefly, Pyrocoelia rufa, were investigated on the midsouthern Korean mainland, coastal islets, a remote offshore island, Jedu-do, and Tsushima Island in Japan. Analysis of DNA sequences from the mitochondrial COI protein-coding gene revealed 20 mtDNA-sequence-based haplotypes with a maximum divergence of 5.5%. Phylogenetic analyses using PAUP, PHYLIP, and networks subdivided the P. rufa into two clades (termed clade A and B) and the minimum nucleotide divergence between them was 3.7%. Clade A occurred throughout the Korean mainland and the coastal islets and Tsushima Island in Japan, whereas clade B was exclusively found on Jeju-do Island. In the analysis of the population genetic structure, clade B formed an independent phylogeographic group, but clade A was further subdivided into three groups: two covering western and eastern parts of the Korean peninsula, respectively, and the other occupying one eastern coastal islet and Japanese Tsushima Island. Considering both phylogeny and population structure of P. rufa, the Jeju-do Island population is obviously differentiated from other P. rufa populations, but the Tsushima Island population was a subset of the Korean coastal islet, Geoje. We interpreted the isolation of the Jeju-do population and the grouping of Tsushima Island with Korean coastal islets in terms of Late Pleistocene-Holocene events. The eastern-western subdivision on the Korean mainland was interpreted partially by the presence of a large major mountain range, which bisects the midpart of the Korean peninsula into western and eastern parts.