Methylation status of Sillago japonica satellite DNA examined by bisulfite modification

Epigenomics in marine fishes

Epigenetic mechanisms are an underappreciated and often ignored component of an organism's response to environmental change and may underlie many types of phenotypic plasticity. Recent technological advances in methods for detecting epigenetic marks at a whole-genome scale have launched new opportunities for studying epigenomics in ecologically relevant non-model systems. The study of ecological epigenomics holds great promise to better understand the linkages between genotype, phenotype, and the environment and to explore mechanisms of phenotypic plasticity. The many attributes of marine fish species, including their high diversity, variable life histories, high fecundity, impressive plasticity, and economic value provide unique opportunities for studying epigenetic mechanisms in an environmental context. To provide a primer on epigenomic research for fish biologists, we start by describing fundamental aspects of epigenetics, focusing on the most widely studied and most well understood of the epigenetic marks: DNA methylation. We then describe the techniques that have been used to investigate DNA methylation in marine fishes to date and highlight some new techniques that hold great promise for future studies. Epigenomic research in marine fishes is in its early stages, so we first briefly discuss what has been learned about the establishment, maintenance, and function of DNA methylation in fishes from studies in zebrafish and then summarize the studies demonstrating the pervasive effects of the environment on the epigenomes of marine fishes. We conclude by highlighting the potential for ongoing research on the epigenomics of marine fishes to reveal critical aspects of the interaction between organisms and their environments.

Novel methylation at GpC dinucleotide in the fish Sparus aurata genome

To date, vertebrate DNA has been found methylated at the 5' position of cytosine exclusively in dinucleotide CpG or CpNpG stretches. On the the other hand, we determined that cytosine was methylated unusually in dinucleotide GpC at 5'-GGCC-3' sequences in the teleost Sparus aurata EcoRI satellite DNA family. This finding is the first example of methylated GpC sequences in the eukaryotic genomes. At this regard, we have examined the relative methylation levels at this site of the highly repetitive EcoRI satellite DNA family from Sparus aurata different tissues. The EcoRI repeat was remarkably more methylated in male germ cells but hypomethylated in female germ cells at the Hae III restriction site (GpC). The novel modification and the differential methylation pattern suggest that EcoRI satellite could have a structural and/or functional role at the centromeres of Sparus aurata.

A novel unusual DNA structure formed in an inverted repeat sequence

A potential to form a non-cruciform unusual DNA structure was shown at the inverted repeat DNA sequence of a fish satellite DNA. The recombinant plasmid harboring a member of the EcoRI satellite family of Sillago japonica (Percoidei, Sillaginidae) was subjected to S1 nuclease treatment, and the cutting sites were mapped by primer extension assay. The S1 nuclease attacked the 3'-half of the inverted repeat but not the middle part of symmetry under various salt conditions, suggesting that this unusual DNA structure is different from the DNA cruciform and a conventional intramolecular triplex structure. In the presence of 200 mM potassium chloride, the typical DNA cruciform has extruded, suggesting that certain purine-purine-pyrimidine base triads are involved in the formation of this unusual DNA structure. These results support the occurrence of a novel unusual DNA structure formed in the inverted repeat sequence.