Thermal ecology of brook trout (Salvelinus fontinalis) and Atlantic salmon (Salmo salar) in impounded streams : behavioural responses and population impacts /

Macmillan, John Leland.

January 1900

Thesis (M.Sc.)--Acadia University, 1999. / Includes bibliographical references (leaves 57-64). Also available on the Internet via the World Wide Web.

The isolation and characterization of troponin T from the slow and fast myotomal muscles of Atlantic salmon /

Waddleton, Deena Maureen,

January 1997

Thesis (M.Sc.)--Memorial University of Newfoundland, 1997. / Bibliography: leaves 107-118.

Kin discrimination in juvenile Atlantic salmon (Salmo salar) and brook trout (Salvelinus fontinalis) : recognition cues and function /

Rajakaruna, Rupika Subashini,

January 2002

Thesis (Ph.D.)--Memorial University of Newfoundland, 2003. / Bibliography: leaves 100-121.

Smoltification and early sexual maturation in the Baltic salmon, Salmo salar L.

Rydevik, Magnus.

January 1989

Thesis (doctoral)--University of Stockholm, 1989. / Includes bibliographical references.

Some characteristics of the Baltic salmon (Salmo salar) L., population individual growth, exploitation pattern and total mortality, from the smolt stage, as revealed by Swedish smolt taggings /

Larsson, Per-Olov.

January 1983

Thesis (doctoral)--University of Stockholm, 1983. / Includes bibliographical references.

Dynamics of planktonic larval sea louse distribution in relation to Atlantic salmon (Salmo salar L.) farms in a Scottish sea loch

Penston, Michael.

January 2009

Thesis (Ph.D.)--Aberdeen University, 2009. / Title from web page (viewed on June 26, 2009). With: Spatial and temporal distribution of Lepeophtheirus salmonis (Krøyer) larvae in a sea loch containing Atlantic salmon, Salmo salra L., farms on the north-west coast of Scotland / M. J. Penston ... et al. Journal of fish diseases. 2008: 31, 361-371. With: Reduced Lepeophtheirus salmonis larval abundance in a sea loch on the west coast of Scotland between 2002 and 2006 / Michael J. Penston, Colin P. Millar, Ian Davies. Dis. Aquat. Org. 2008: 81, 109-117. Includes bibliographical references.

Behavior and Survival of Migrating Atlantic Salmon (Salmo salar) in the Penobscot River and Estuary, Maine: Acoustic Telemetry Studies of Smolts and Adults

Holbrook, Christopher Michael

January 2007

No description available.

Atlantic salmon -- Migration

Migratory Urge and gill Na+, K+ -ATPase Activity of Hatchery Reared Atlantic Salmon Smolts from Dennys and Penobscot River Stocks, Maine and Review of Enhancement Programs

Spencer, Randall C.

January 2009

No description available.

Atlantic salmon -- Migration -- Maine

Smolting

Sodium/potassium ATPase

Mapping and functional characterisation of the Atlantic salmon genome and its regulation of pathogen response

Gonen, Serap

January 2015

Atlantic salmon is a species of both scientific and economic importance, and Atlantic salmon farming is a highly profitable industry worldwide. One of the biggest challenges being faced by farms, which affects production efficiency and results in severe economic loss, is disease. In livestock production, one of the approaches taken to limit the impact of disease outbreaks is to selectively breed for improved resistance within farmed populations. Although traditional family-based resistance breeding programs have shown improvements in resistance to a variety of bacterial, viral and parasitic diseases on Atlantic salmon farms, response to selection can be slow. One way of increasing selection efficiency is through the incorporation of genetic markers into breeding programs, for marker-assisted or genomic selection. However, genomic resources for cultured aquatic species are sparse, and the generation of new and denser resources for use in selective breeding programs would be advantageous. The main focus of this thesis is the development of genomic resources in Atlantic salmon and the application of those resources to gain a better understanding of the salmon genome, particularly in the genetic basis of host resistance to infectious diseases. The first aim of this thesis was to develop improved genomic resources for Atlantic salmon, and to characterise the Atlantic salmon genome via construction and analysis of a SNP linkage map derived from RAD-Sequencing (RAD-Seq). Approximately 6,500 SNPs were assigned to 29 linkage groups, and ~1,800 male-segregating, and ~1,400 female-segregating SNPs were ordered and positioned. Overall map lengths and recombination ratios were relatively consistent between the sexes and across the linkage groups (~1:1.5, male:female). However, a substantial difference in the degree of marker clustering was seen between males and females, which is reflective of the difference in the positions of chiasmata between the two sexes. Using this map, ~4,000 Atlantic salmon reference genome contigs were assigned to a linkage group, and 112 contigs were assigned to multiple linkage groups, highlighting regions of homeology (large sections of duplicated chromosomal regions) within the salmon genome. Alignment of SNP-flanking sequences to the stickleback and rainbow trout genomes identified putative gene-associated SNPs and cross-species chromosomal orthologies, and provided evidence in support of the salmonid-specific genome duplication. In addition, based on this and other publically available RAD-Seq datasets, the utility of RAD-Seq-derived data from different species and laboratories for population genetics analyses was tested. Short RAD-Seq contigs in Atlantic salmon and nine other teleost fish were used to identify cross-species orthologous genomic relationships. Several thousands of orthologous RAD loci were identified across the species, with the number of RAD loci decreasing with evolutionary distance, as expected. Previously published broad-level relationships between orthologous chromosomes were confirmed. The identified cross-species orthologous RAD loci were used to estimate evolutionary relationships between the ten teleost fish species. Previously published relationships were recovered, suggesting that RAD-Seq data derived from different laboratories is useful for this purpose. The second aim was to characterise the genetic architecture of resistance to two viral diseases affecting Atlantic salmon production on farms: pancreas disease (PD), and infectious pancreatic necrosis (IPN). Using data and samples collected from a large population of salmon fry challenged with PD, a high heritability for resistance was estimated (h2 ~0.5), and four QTL were identified, on chromosomes 3, 4, 7 and 23. The QTL explaining the highest within-family variation for resistance was located on chromosome 3. This QTL has been confirmed in a population of post-smolts by an independent research group, highlighting the potential for its incorporation into breeding programs to improve PD resistance. For IPN, the major resistance QTL had previously been mapped to linkage group 21. However, the mutation(s) underlying this QTL effect and the consequences of these mutation(s) on the affected genes and relevant biological resistance mechanisms are unknown. To generate a list of candidate genes within the vicinity of the IPN QTL, QTL-linked DNA sequences were aligned to four model fish genomes. This identified two QTL-orthologous regions in each of the species, and gene order within these regions was highly conserved across species. Analysis of gene expression patterns between IPN resistant and susceptible salmon in a viral challenge experiment revealed that the five most significantly differentially-expressed genes mapped to the QTL-orthologous region on linkage group II of stickleback. Pathway enrichment analysis across all differentially-expressed genes suggests that biological pathways influencing viral infection stress response/entry/replication, cellular energy production and apoptosis may be involved in resistance during the initial stages of IPN virus (IPNV) infection. These results have provided the basis for further study of the putative involvement of these candidate genes and pathways in genetic resistance to IPNV. In summary, the results and resources presented in this thesis extend our current understanding of the salmon genome and the genetic basis of resistance to two viral diseases, and provide resources with the potential to be used in Atlantic salmon selective breeding programs to tackle disease outbreaks.

333.95

Population level variation of Atlantic salmon in the chalk streams of southern England and neighbouring regions

Ikediashi, Charles Isioma

January 2015

In this thesis, population level variation is elucidated for Atlantic salmon living in the chalk streams of southern England – a unique and unusual habitat – as well as in immediately surrounding regions. Salmon in these chalk streams have yet to be robustly investigated, despite individual populations standing out from neighbouring populations in several previous studies. This thesis attempts to identify how different they are and the reasons for it. Then, this thesis also investigates the effect of this distinction on their internal population structure, as well as the current and future trajectory. A panel of microsatellite markers from the SALSEA-merge project were used to complete four studies of population structure in Atlantic salmon. In the first study, which served primarily, as a training exercise, a multi-national baseline was used to identify the origins of salmon recolonising the river Mersey in northwest England. Fish entering the Mersey originated from multiple sources, with the greatest proportion (45–60%) assigning to rivers in the geographical region just north of the Mersey, including Northwest England and the Solway Firth. The number of fish originating from proximal rivers to the west of the Mersey was lower than expected. The results suggested that the recolonisers were straying in accordance with the predominantly clockwise gyre present in the eastern Irish Sea. In the second study, the relationship of salmon in the chalk streams of southern England to salmon outside this region was elucidated. Salmon from all five chalk streams in southern England with major salmon populations were found to all be genetically distinct from these neighbours and statistically less genetically diverse than salmon in southwest England and France. The reasons for this were relatively low immigration and a history of low effective population size. In the third study, the extent of population structure of salmon between the chalk streams and within one chalk stream, the river Frome, was explored. The results suggested these salmon were divided into three groups, i.e. 1) the Frome & Piddle, 2) the Avon and 3) the Test & Itchen. A significant pattern of isolation by distance between salmon in these five rivers was also identified. Historic samples from the Avon were assigned to the contemporary three groups. Surprisingly, most of these fish assigned to the Frome and Piddle group. Within the river Frome, further sub-structure was identified over two separate years of sampling. Salmon from 2009 comprised three genetic groups, and salmon in 2011 comprised just two. In the fourth study, historic scale samples were used to assess the current trajectory of genetic diversity and effective population size of salmon populations across Scotland, England, Wales and France. The majority of samples greater than 30 years old proved ineffective using the SALSEA panel. However, data was compiled from samples from eight rivers ranging from the Tweed in Scotland to the Scorff in France and from 1972 to 2012. Contrary to our hypothesis, most populations showed increases in allelic richness. Populations from one chalk stream show the steepest temporal decline in genetic diversity, which we speculate is partly due to the low immigration into the region. Effective population size proved difficult to determine using a number of methods and no robust pattern was identified. Together these studies indicate that low immigration of salmon into the chalk streams appears to be key to their low genetic diversity and genetic distinction. Low immigration may also have enabled marked within-river population structure and the current negative trajectory of genetic diversity. The implications for general understanding of Atlantic salmon population structure across their range, and for the conservation of this species are discussed.

597.5