Phylogeography of Japanese population of Phelotrupes auratus (Coleoptera, Geotrupidae) inferred from mitochondrial DNA sequences.

A partial sequence of the mitochondrial cytochrome c oxidase subunit I (COI) gene (745 bp) was determined for 57 specimens of a geotrupid beetle (Phelotrupes auratus) from throughout the Japanese archipelago. Of the 57 beetles examined, 42 haplotypes were identified. Phylogenetic trees inferred using maximum parsimony, neighbor joining, and Bayesian inference methods were highly congruent. Reconstructed phylogenetic relationships indicated that P. auratus from the Japanese archipelago was separated into two distinct lineages: Group A, which consisted of 35 haplotypes from Honshu, Shikoku, and Hokkaido Islands, and Group B, which consisted of seven haplotypes from Kyushu and Yakushima Islands. In addition, two sublineages were also recognized within Group A: Subgroup A-1, which consisted of 11 haplotypes from eastern Honshu and Hokkaido, and Subgroup A-2, which consisted of 10 haplotypes from western Honshu and Shikoku. Average genetic distances within Group A were positively correlated to geographic distance between sampling localities. Phylogenetic relationships among haplotypes did not correspond to subspecies classification.

Spawning of the kissing loach (Leptobotia curta) is limited to periods following the formation of temporary waters.

The kissing loach, an endangered species surviving only in a few Japanese rivers, spawns in the rice-field areas after migration from rivers in early June. To characterize the environmental conditions required for spawning of the kissing loach, spawning was assessed for two years both by direct observation of spawning behavior and by the appearance of eggs, larvae, and juveniles from June to October. All spawning of the kissing loach was limited to within a couple of days after the formation of temporary waters by remarkable rises in water level. Water temperature and daily rainfall fluctuated during the investigation periods, and no clear relationships with spawning were detected. Furthermore, all spawning was observed only in temporary waters with terrestrial grasses. Thus, spawning of the kissing loach is rigidly limited spatio-temporally to after the formation of temporary waters over terrestrial vegetation. Appropriate management of temporary waters will be crucial for the continued existence of this species.

Spawning behavior of the kissing loach (Leptobotia curta) in temporary waters.

The natural spawning behavior of the kissing loach, an endangered species of Botiidae, was investigated in the wild in early June for two years in relation to several environmental factors. Kissing loaches spawned in temporary waters after elevation in water level. All spawnings observed (n=163) occurred within 3-5.5 hours from late afternoon to night after formation of the temporary water. These spawnings were performed by one female and one (71%) or two (29%) males in densely vegetated lentic waters. The female and following male(s) swam into dense grasses, where they vibrated to spawn intermittently. After the vibration continuing for 3-20 seconds, they moved to other parts of the dense grassy area and began vibration again. This sequence of spawning behavior was usually repeated several times, and the eggs were thus scattered widely. The spawning behavior and the rapid larval development of this species appear to be adaptations for the use of temporary waters as a spawning ground. The rise in water level and the consequent formation of temporary waters appear to be crucial triggers for reproduction of the kissing loach.

Phylogenetic analyses of fat body endosymbionts reveal differences in invasion times of blaberid wood-feeding cockroaches (Blaberidae: Panesthiinae) into the Japanese archipelago.

Cockroaches have endosymbiotic bacteria in their fat bodies. Recent molecular phylogenetic analyses on both hosts and endosymbionts have revealed that co-evolution has occurred throughout the history of cockroaches and termites. Co-cladogenesis was also shown among closely related taxa (woodroach genus Cryptocercus; Cryptocercidae), and thus endosymbiont data are likely to be useful for biogeographical analyses. To test the possibility of co-cladogenesis among inter-and intraspecific taxa, as well as the utility of endosymbiont data for inferring biogeographical scenarios, we analyzed rRNA genes of endosymbionts of Japanese and Taiwanese Panesthiinae (Salganea and Panesthia; Blaberidae), on which phylogenetic analyses previously had been performed based on the mitochondrial genes. Statistical analyses on the topologies inferred from both endosymbiont and host mitochondria genes showed that co-cladogenesis has occurred. The endosymbiont sequences examined appear to have evolved in a clock-like manner, and their rate of evolution based on the host fossil data showed a major difference in the time of invasion of the two Japanese genera, that is congruent with the recent analyses of their mitochondrial genes.