Difference in evolutionary patterns of strongly or weakly selected characters among ant populations.

Despite being a central issue in evolutionary biology, few studies have examined the stasis of characters in populations with no gene flow. A possible mechanism of such stasis is stabilizing selection with similar peaks in each population. This study examined the evolutionary patterns of morphological characters with and without strong selection in ant populations. We show that compared to a character that seems to be less important, characters that are more important were less variable within and among populations. Microsatellite analyses showed significant genetic differences between populations, implying limited gene flow between them. The observed levels of genetic differentiation cannot be attributed to recent population separations. Thus, the observed differences in morphological variance seem to reflect the degree of selection on each character. The less important character changed proportionately with time, but such a pattern was not observed in more important characters. These results suggest that stabilizing selection maintains morphological stasis between populations of the same species with minimal gene flow independent of divergence times.

The genome size evolution of medaka (Oryzias latipes) and fugu (Takifugu rubripes).

Evolution of the genome size in eukaryotes is often affected by changes in the noncoding sequences, for which insertions and deletions (indels) of small nucleotide sequences and amplification of repetitive elements are considered responsible. In this study, we compared the genomic DNA sequences of two kinds of fish, medaka (Oryzias latipes) and fugu (Takifugu rubripes), which show two-fold difference in the genome size (800 Mb vs. 400 Mb). We selected a contiguous DNA sequence of 790 kb from the medaka chromosome LG22 (linkage group 22), and made a precise comparison with the sequence (387 kb) of the corresponding region of Takifugu. The sequence of 178 kb in total was aligned common between two fishes, and the remaining sequences (612 kb for medaka and 209 kb for fugu) were found abundant in various repetitive elements including many types of unclassified low copy repeats, all of which accounted for more than a half (54%) of the genome size difference. Furthermore, we identified a significant difference in the length ratio of the unaligned sequences that locate between the aligned sequences (USBAS), particularly after eliminating known repetitive elements. These USBAS with no repetitive elements (USBAS-nr) located within the intron and intergenic region. These results strongly indicated that amplification of repetitive elements and compilation of indels are major driving forces to facilitate changes in the genome size.

The DNA sequence of medaka chromosome LG22.

We report the genomic DNA sequence of a single chromosome (linkage group 22; LG22) of the small teleost fish medaka (Oryzias latipes) as a first whole chromosome sequence from a non-mammalian vertebrate. The order and orientation of 633 protein-coding genes were deduced from 18,803,338 bp of DNA sequence, providing the opportunity to analyze chromosome evolution of vertebrate genomes by direct comparison with the human genome. The average number of genes in the "conserved gene cluster" (CGC), a strict definition of "synteny" at the sequence basis, between medaka and human was 1.6. These and other data suggest that approximately 38.8% of pair-wise gene relationships would have been broken from their common ancestor in the human and medaka lineages and further imply that approx 20,000 (15,520-23,280) breaks would have occurred from the entire genome of the common ancestor. These breaks were generated mainly by intra-chromosomal shufflings at a specific era in the vertebrate lineage. These precise comparative genomics allowed us to identify the pieces of ancient chromosomes of the common vertebrate ancestor and estimate chromosomal evolution in the vertebrate lineage.

Genomic organization of the sex-determining and adjacent regions of the sex chromosomes of medaka.

Sequencing of the human Y chromosome has uncovered the peculiarities of the genomic organization of a heterogametic sex chromosome of old evolutionary age, and has led to many insights into the evolutionary changes that occurred during its long history. We have studied the genomic organization of the medaka fish Y chromosome, which is one of the youngest heterogametic sex chromosomes on which molecular data are available. The Y specific and adjacent regions were sequenced and compared to the X. The male sex-determining gene, dmrt1bY, appears to be the only functional gene in the Y-specific region. The Y-specific region itself is derived from the duplication of a 43-kb fragment from linkage group 9. All other coduplicated genes except dmrt1bY degenerated. The Y-specific region has accumulated large stretches of repetitive sequences and duplicated pieces of DNA from elsewhere in the genome, thereby growing to 258 kb. Interestingly the non-recombining part of the Y did not spread out considerably from the original duplicated fragment, possibly because of a large sequence duplication bordering the Y-specific fragment. This may have conserved the more ancestral structure of the medaka Y and provides insights into some of the initial processes of Y chromosome evolution.

Color reversion of the albino medaka fish associated with spontaneous somatic excision of the Tol-1 transposable element from the tyrosinase gene.

The medaka fish albino mutant, i(1) is one of the Tomita collection of medaka pigmentation mutants which exhibits a complete albino phenotype, because of inactivation of the tyrosinase gene due to insertion of a transposable element, Tol-1. Recently, mosaic black-pigmented i(1) medaka fish have arisen in one of our laboratory breeding populations. Their pigmented cells have been observed in all of the tissues, including the eye and skin, in which melanin is detectable in the wild type. In this study, we analyzed the tyrosinase gene of revertants and showed Tol-1 to have been precisely excised from the gene, suggesting a causal relationship. Mosaic patterns of pigmentation indicate spontaneous somatic excision of the element from the tyrosinase gene. To our knowledge, this is the first transposable element with somatic excision activity demonstrated phenotypically in vertebrates. The pattern of pigmentation in mosaic revertants indicates frequencies of melanin pigments to be consistent with the numbers of melanophores per unit area of body sites, such as the eyes, head and dorsal trunk.

Comparative genomics of medaka and fugu.

A small freshwater fish medaka (Oryzias latipes) has been one of the most attractive experimental systems for research in genetics and developmental biology. We have formed an international consortium Medaka Genome Initiative (MGI) to collect and share various information and resources on medaka. The MGI has set an ambitious goal aiming at the complete sequencing of the medaka genome and as a feasibility study we have begun sequencing one particular chromosome, linkage group 22 (LG22) of approximately 22 Mb in size. Initial sequence analysis revealed unique features of the medaka genome in comparison to fugu genome.