The genome sequence of the sardine, (Walbaum, 1792).

We present a genome assembly from an individual (the sardine; Chordata; Actinopteri; Clupeiformes; Clupeidae). The genome sequence spans 869.40 megabases.

The genome sequence of the cuckoo wrasse, Linnaeus 1758.

We present a genome assembly from an individual (the cuckoo wrasse; Chordata; Actinopteri; Labriformes; Labridae). The genome sequence has a total length of 740.60 megabases.

The genome sequence of the European conger eel, (Linnaeus, 1758).

We present a genome assembly from an individual (the European conger eel; Chordata; Actinopteri; Anguilliformes; Congridae). The genome sequence spans 1,136.40 megabases.

The genome sequence of the grey gurnard, (Linnaeus, 1758).

We present a genome assembly from an individual (the grey gurnard; Chordata; Actinopteri; Scorpaeniformes; Triglidae). The genome sequence is 680.5 megabases in span.

The genome sequence of the blonde ray, Lafont, 1871.

We present a genome assembly from an individual female (Blonde Ray; Chordata; Chondrichthyes; Rajiformes; Rajidae). The genome sequence spans 2,700.50 megabases.

The genome sequence of the thickback sole, (Donovan, 1808).

We present a genome assembly from an individual female (the thickback sole; Chordata; Actinopteri; Pleuronectiformes; Soleidae). The genome sequence is 724.7 megabases in span.

The genome sequence of the John Dory, Linnaeus, 1758.

We present a genome assembly from an individual (the John Dory; Chordata; Actinopteri; Zeiformes; Zeidae). The genome sequence is 804.7 megabases in span.

The genome sequence of the greater pipefish, (Linnaeus, 1758).

We present a genome assembly from an individual (the greater pipefish; Chordata; Actinopteri; Syngnathiformes; Syngnathidae). The genome sequence is 359.2 megabases in span.

The genome sequence of the European plaice, (Linnaeus, 1758).

We present a genome assembly from an individual (the European plaice; Chordata; Actinopteri; Pleuronectiformes; Pleuronectidae). The genome sequence is 687.4 megabases in span.

Natal foraging philopatry in eastern Pacific hawksbill turtles.

The complex processes involved with animal migration have long been a subject of biological interest, and broad-scale movement patterns of many marine turtle populations still remain unresolved. While it is widely accepted that once marine turtles reach sexual maturity they home to natal areas for nesting or reproduction, the role of philopatry to natal areas during other life stages has received less scrutiny, despite widespread evidence across the taxa. Here we report on genetic research that indicates that juvenile hawksbill turtles () in the eastern Pacific Ocean use foraging grounds in the region of their natal beaches, a pattern we term natal foraging philopatry.