Population origin of Atlantic sturgeon Acipenser oxyrinchus oxyrinchus by-catch in U.S. Atlantic coast fisheries.

Microsatellite DNA and mitochondrial DNA control-region sequence analyses were used to determine the population and distinct population segment (DPS) origin of 173 Atlantic sturgeon Acipenser oxyrinchus oxyrinchus encountered from the Gulf of Maine to Cape Hatteras, North Carolina, in NOAA's Northeast Fisheries Observer Program. It was found that the Hudson River was by far the greatest contributor to this coastal by-catch, with 42·2-46·3% of specimens originating there. Generally, specimens represented the geographic province of the river in which they were spawned, but some specimens, particularly those originating in the South Atlantic DPS, moved to great distances. Genetic mixed-stock analyses provide an accurate approach to determine the DPS and population origin of A. o. oxyrinchus by-catch in coastal waters, but most informative management requires that these results be partitioned by locale, season, target fishery and gear type.

An evaluation of introgression of Atlantic coast striped bass mitochondrial DNA in a Gulf of Mexico population using formalin-preserved museum collections.

Striped bass Morone saxatilis populations in drainages along the Gulf of Mexico coast (Gulf) were depleted in the 1950s and 1960s, probably because of anthropogenic influences. It is believed that only the Apalachicola-Chattahoochee-Flint (A-C-F) river system continually supported a naturally reproducing population of Gulf lineage. Striped bass juveniles of Atlantic coast (Atlantic) ancestry were introduced to restore population abundances in the A-C-F from the late 1960s to the mid 1970s and in many other Gulf rivers from the 1960s to the present. We previously identified mtDNA polymorphisms that were unique to approximately 60% of striped bass from the A-C-F and which confirmed the continued successful natural reproduction of striped bass of Gulf maternal ancestry within the system. However, the genetic relatedness of the extant A-C-F population to 'pure' Gulf striped bass was not addressed. In this study, we determined the frequency of a diagnostic mtDNA XbaI polymorphism in samples of 'pure' Gulf striped bass that were collected from the A-C-F prior to the introduction of Atlantic fish, that were obtained from museum collections, and that were originally preserved in formalin. PCR primers were developed that allowed for amplification of a 191-bp mtDNA fragment that contained the diagnostic XbaI restriction site. Using RFLP and direct sequence analyses of the PCR amplicons, we found no significant differences in mtDNA XbaI genotype frequencies between the archived samples and extant A-C-F samples collected over a 15-year period. This indicates that significant maternally mediated introgression of Atlantic mtDNA genomes into the A-C-F gene pool has not occurred. Additionally, we found no evidence of the unique Gulf mtDNA genotype in striped bass from extant populations in Texas, Louisiana and the Mississippi River. These results highlight the importance of the A-C-F as a repository of striped bass to restore extirpated Gulf populations and the potential use of museum collections in retrospective population studies.

Use of cellular oncogene probes to identify Morone hybrids.

We tested the ability of cellular oncogene (c-onc) probes to identify F1 hybrids and the lineage of known backcrosses within the fish genus Morone. Total DNA was isolated from five to 14 individuals per North American Morone species (striped bass, white bass, white perch, and yellow bass). The DNA was digested with two restriction enzymes, Eco RI and Hin dIII, Southern blotted, and hybridized to six different c-onc probes including v-abl, v-erb B, c-myc, c-H-ras, c-K-ras, and v-src. We found fixed genotypic differences among the four species for all six probes in single restriction enzyme digests. The heritability of these nuclear DNA genotypes was evaluated in hatchery-produced F1 Morone hybrids (striped bass x white bass and striped bass x white perch) tested with the six informative single probe/restriction enzyme combinations. All F1 individuals exhibited heterozygosity in all diagnostic nuclear DNA fragments, confirming the Mendelian inheritance of these genotypes in these fish. Furthermore, analysis of these nuclear DNA genotypes in hatchery-produced backcrosses of F1 hybrids striped bass x (white bass x striped bass) detected both recombinant and parental genotypes at all six polymorphic c-onc sequences. The lineage of suspected Morone hybrids of unknown descent collected from Lewis Smith Lake, Alabama, and from the Occoquan River, Virginia, was determined using the c-onc probes. Our results suggest that c-onc probes are suitable markers to unequivocally identify F1 hybrids and backcrosses and to quantify introgression in natural populations of fishes. The addition of RFLP analysis of mtDNA provided a complete ancestral history of individual fish.