Dynamics of Laterality in Relation to the Predator-Prey Interaction between the Piscivorous Chub "Hasu" and Its Prey "Ayu" in Lake Biwa.

A Japanese piscivorous chub, "hasu" (Opsariichthys uncirostris), and its main prey, "ayu" (Plecoglossus altivelis), both have laterally asymmetric bodies, similar to other fishes; each population consists of righty morphs and lefty morphs. This antisymmetric dimorphism has a genetic basis. Temporal changes in the ratios of laterality (i.e., frequency of righty morphs in a population) of these predator and prey fish species were investigated for a 20-year period at a pelagic site in the southwestern area of Lake Biwa, Japan. The dimorphism of each species was maintained dynamically throughout the period, and the ratio of laterality was found to change periodically in a semi-synchronized manner. Direct inspection of the relationship between the ratios of laterality of the two species indicated that the ratio of ayu followed that of hasu, suggesting that the predator-prey interaction was responsible for the semi-synchronized change. Stomach contents analysis of each hasu revealed that cross-predation, in which righty predators catch lefty prey and lefty predators catch righty prey, occurred more frequently than the reverse combination (parallel-predation). This differential predation is presumed to cause frequency-dependent selection on the two morphs of the predator and prey, and to drive semi-synchronized changes in the laterality of the two species. Some discussion pertaining to the atypical form of the semi-synchronized change in laterality found in this study is presented from the viewpoint of predator-prey interaction in fishes.

Fine-scale genetic structure of the endangered bitterling in the middle river basin of the Kiso River, Japan.

Recently, anthropogenic alterations have had severe and negative impacts on the terrestrial and aquatic species and environments. To conserve species that have a small and limited habitat, it is necessary to focus on fine-scale population structure and its effects on persistence. The deepbodied bitterling Acheilognathus longipinnis is an endangered freshwater fish that occupies ponds scattered in lateral bars in the Kiso River. In this study, we conducted multi-locus microsatellite DNA analysis to evaluate both fine-scale population structure and genetic diversity, in order to conserve A. longipinnis. The smaller number of loci deviating from the Hardy-Weinberg equilibrium in ponds scattered in individual lateral bars compared to the whole river system suggests that A. longipinnis forms a local breeding population in units of ponds. The population was roughly split between the river banks and the local population located in ponds in the mid-channel bar showed intermediate relationships with the river bank populations. Gene flow between local populations was not always homogeneous and was not influenced by geographical distances between local populations or the direction of river flow. The dispersal of A. longipinnis across both river bank sides may be constrained and is probably affected by the ecological characteristics of A. longipinnis and the hydrological regimes. Consequently, A. longipinnis in the Kiso River is maintained as a complex of multiple local populations with appropriate gene flow among them. To conserve A. longipinnis, both the persistence of the unstable ponds and moderate genetic exchanges by individual migration are required.

Genetic Characteristics of the Japanese Serow Capricornis crispus in the Kii Mountain Range, Central Japan.

The Japanese serow, Capricornis crispus, is an indigenous bovid species exclusively inhabiting mountain regions in the main Japanese islands, excepting Hokkaido. It had decreased in abundance to its lowest level due to overhunting and deforestation, with its distribution severely fragmented from the middle of the 20th century, many populations of C. crispus currently facing the risk of extinction. The Kii Mountain Range (KM) on Honshu is one such location that has seen a drastic population decline of C. crispus. In this study, we examined genetic characteristics of C. crispus in KM and neighboring regions of the Chubu district, using mtDNA and microsatellite markers, in order to devise strategies for its conservation. Results for mtDNA were characterized by low nucleotide diversity with five endemic and two dominant haplotypes shared by individuals in neighboring regions. A Bayesian skyline plot indicated a gradual increase after the last glacial maximum. For microsatellites, the genetic diversity of C. crispus in KM was comparable to Shizuoka and higher than Shikoku. Recent genetic bottlenecks were strongly suggested in C. crispus in KM. Bayesian clustering showed a genetic cline between KM and neighboring regions, where multivariate analysis suggested three local populations. A Mantel test indicated male-biased dispersal. These results indicate that C. crispus in KM and neighboring regions constitute multiple local populations, connected through restricted gene flow. For the conservation of C. crispus, it is important to define small-scale conservation units, among which genetic connectivity should be facilitated to prevent further loss of genetic diversity.

The complete mitochondrial genomes of two endangered bitterling Acheilognathus tabira tohokuensis and A. tabira erythropterus (Cyprinidae, Acheilognathinae).

Acheilognathus tabira (tabira bitterling) comprises of 5 subspecies, all of which are endangered. In this study, the mitochondrial genome (mitogenome) of the 2 subspecies, A. tabira tohokuensis and A. tabira erythropterus, whose mitogenomes have not been reported previously, was determined. The total lengths of A. tabira tohokuensis and A. tabira erythropterus mitogenomes were 16,774 bp and 16,770 bp, respectively, and were noted as slightly AT-rich. Phylogenetic analysis revealed that these 2 subspecies of A. tabira were the most closely related, out of the 5 subspecies. The deciphered mitogenomes would be useful for conservation and evolutionary studies.

Phylogeography of Endangered Bitterling Acheilognathus melanogaster Endemic to Eastern Japan.

The bitterling Acheilognathus melanogaster is a critically endangered primary freshwater fish endemic to the Pacific side of eastern Japan. To elucidate A. melanogaster genetic structure, we investigated phylogeography in nine populations, using gene sequences of mitochondrial Cytochrome b (Cytb), as well as nuclear Rhodopsin (Rho) and glycosyltransferase (Glyt). We found four Cytb-based geographical clusters unevenly divided between the northern and southern regions, with smaller groups in the south. Of the nuclear genes, Glyt did not show geographical differentiation, whereas Rho formed two clusters: one widely occurring and another restricted to central regions. Genetic diversity was generally higher in southern than in northern populations. Our results suggest that conservation of southern local populations is particularly important in maintaining the genetic diversity of this endangered fish.

Photo images, 3D models and CT scanned data of loaches (Botiidae, Cobitidae and Nemacheilidae) of Japan.

BACKGROUND: Loach is one of the major cypriniform fishes in freshwater habitats of Japan; 35 taxa/clades have, until now, been recognised. Parallel to genetic studies, morphological examinations are needed for further development of loach study, eventually ichthyology and fish biology. Digital archiving, concerning taxonomy, ecology, ethology etc., is one of the progressive challenges for the open science of biology. This paper aimed to online publish photo images, 3D models and CT scanned data of all the known clades of loaches inhabiting Japan (103 individuals in total with several type specimens), contributing to ichthyology and public interest of biodiversity/biology. NEW INFORMATION: Photo images, 3D models and CT scanned data of all the known 35 taxa/clades of loaches inhabiting in Japan were online published at http://ffish.asia/loachesOfJapan and http://ffish.asia/loachesOfJapan3D.

Laterality is Universal Among Fishes but Increasingly Cryptic Among Derived Groups.

Laterality has been studied in several vertebrates, mainly in terms of brain lateralization and behavioral laterality, but morphological asymmetry has not been extensively investigated. Asymmetry in fishes was first described in scale-eating cichlids from Lake Tanganyika, in the form of bilateral dimorphism in which some individuals, when opening their mouths, twist them to the right and others to the left. This asymmetry has a genetic basis, and is correlated with lateralized attack behaviors. This has subsequently been found in fishes from numerous taxa with various feeding habits. The generality of such morphological laterality should thus be investigated in as wide a range of fishes as possible. Using specific indicators of lateral differences in mandibles and head inclination, we find that representative species from all 60 orders of extant gnathostome fishes (both bony and cartilaginous) possess morphological laterality. Furthermore, we identify the same laterality in agnathans (hagfish and lamprey), suggesting that this trait appeared early in fish evolution and has been maintained across fish lineages. However, a comparison of asymmetry among groups of bony fishes reveals, unexpectedly, that phylogenetically more recent-groups possess less asymmetry in body structures. The universality of laterality in fishes indicates a monophyletic origin, and may have been present in the ancestors of vertebrates. Ecological factors, predator-prey interactions in particular, may be key drivers in the evolution and maintenance of dimorphism, and may also be responsible for the cryptic trend of asymmetry in derived groups. Because lungfish and coelacanths share this trait, it is likely that tetrapods also inherited it. We believe that study of this morphological laterality will provide insights into the behavioral and sensory lateralization of vertebrates.