The feeding behaviour of cultured and wild Atlantic salmon, Salmo salar L., in the Louvenga River, Kola Peninsula, Russia

Орлов, А. В.; Gerasimov, Yu. V.; Лапшин, О. М.

doi:10.1016/j.icesjms.2006.05.004

Cited by 43 publications

(52 citation statements)

References 29 publications

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“…Although poor in absolute numbers of OTUs (that is, richness), diversity estimates from returning adults were not significantly different from juveniles, suggesting a fairly even frequency distribution of those OTUs present. Dietary complexity in juvenile salmonids could explain rich associated microbial assemblages (Orlov et al, 2006). Meanwhile physiological disturbances and fasting in migratory phases (smolt and returning adults) could underlie reduced community stability with respect to corresponding non-migratory phases (that is, parr and marine adults, Figure 1b).…”

Section: Discussionmentioning

confidence: 99%

“…Growth, development and migration in anadromous S. salar involves a radical shift across an ecological and trophic spectrum (Jacobsen and Hansen, 1999;Orlov et al, 2006). Accompanying the physiological, behavioural and dietary adaptations necessary to cope with transition between freshwater and marine environments (McCormick et al, 2013), significant and potentially adaptive shifts in host-associated microbiota might be expected.…”

Section: Introductionmentioning

confidence: 99%

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The biogeography of the atlantic salmon (Salmo salar) gut microbiome

et al. 2015

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Although understood in many vertebrate systems, the natural diversity of host-associated microbiota has been little studied in teleosts. For migratory fishes, successful exploitation of multiple habitats may affect and be affected by the composition of the intestinal microbiome. We collected 96 Salmo salar from across the Atlantic encompassing both freshwater and marine phases. Dramatic differences between environmental and gut bacterial communities were observed. Furthermore, community composition was not significantly impacted by geography. Instead life-cycle stage strongly defined both the diversity and identity of microbial assemblages in the gut, with evidence for community destabilisation in migratory phases. Mycoplasmataceae phylotypes were abundantly recovered in all life-cycle stages. Patterns of Mycoplasmataceae phylotype recruitment to the intestinal microbial community among sites and life-cycle stages support a dual role for deterministic and stochastic processes in defining the composition of the S. salar gut microbiome.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The biogeography of the atlantic salmon (Salmo salar) gut microbiome

et al. 2015

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“…In the wild, domestic salmon exhibit lower fitness than wild salmon and aquaculture escapes can endanger natural populations compromising their viability (Clifford et al 1998;McGinnity et al 1998McGinnity et al , 2003McGinnity et al , 2009. Domestication encompasses genetic changes in life-history traits, which can be subjected to directional selection in farm conditions (Fleming and Einum 1997;Hindar et al 2006) and also in behavioral components such as aggressiveness, mate choice and others (Fleming and Gross 1993;Fleming et al 2000Fleming et al , 2002MignonGrasteau et al 2005;Orlov et al 2006;Castillo et al 2008). As an indicator of such altered behavior, individuals of domestic origin provide most hybrid crosses between Atlantic salmon and brown trout in southern Europe (Castillo et al 2008).…”

Section: Discussionmentioning

confidence: 99%

Not all lineages are equally invasive: genetic origin and life-history in Atlantic salmon and brown trout acclimated to the Southern Hemisphere

et al. 2010

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Salmonids are fish from the Northern Hemisphere which have been introduced and acclimated to many regions in the Southern Hemisphere for commercial (aquaculture) and recreational (sport fishing) purposes. In some cases a species like brown trout Salmo trutta rapidly spread across the host ecosystem and became invasive, threatening local fauna, and even outcompeting other exotic fish. We have analyzed life-history traits in combination with genetic variation of Atlantic salmon and brown trout adapted to the lake systems of the Argentinean Patagonia (South America). We have identified two main characteristics that conferred invasive capacity to those exotic species: undomesticated status and lifelong growth. Stocks originated from wild populations adapted better than long-term domestic lineages, and their geographic origin seems to be less important for adaptation to exotic environments. We propose that considering these characteristics in future planning of commercial aquaculture projects by selecting non-invasive lineages will minimise the impact of accidental escapes.

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“…For example, compared to hatchery-reared fish from unselected lines, coho salmon (Oncorhynchus kisutch) selected for rapid growth over many generations ingest more food, grow faster and grow more efficiently; fish of the selected line seem to be particularly efficient at using lipids for energy, sparing protein for growth (Figure 7.20;Neely et al 2008). Considering the post-release effects of domestication and captive rearing, wild juvenile Atlantic salmon have fuller stomachs than do hatchery-reared fish soon after release, though this difference is short-lived (Orlov et al 2006) and no differences are reported between domesticated and wild brown trout (Johnsson et al 1996). Finally, captive-bred butterfly splitfins (Ameca splendens) are less likely to feed and more likely to fight than are wild fish (Kelley et al 2006).…”

Section: Domestication and Captive Rearing Effects On Feed Intakementioning

confidence: 99%

Appetite and Feed Intake

Jobling

Alanärä

Noble

et al. 2012

Aquaculture and Behavior

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This chapter first describes changes in appetite that occur over different time scales in wild fish and the physiological mechanisms that generate these changes. It then gives an account of how food intake and appetite change as young fish develop and mature and the effects of genetic variation and differential experience on these processes. The costs of sustaining a high rate of food intake are then described, as is the way in which these are balanced against the obvious benefits of gaining a good supply of nutrients. The benefits gained by regular appetite cycles are also considered. The implications of natural appetite patterns for fish culture are then discussed, including problems arising from underfeeding and overfeeding and those resulting from failure to match feed delivery to current appetite. Underfeeding causes slow, uneven growth and high levels of aggression, as well as stress and mortality, while overfeeding may result in inefficient production and adverse environmental impact. Potential solutions to such problems are discussed, including the use of on-demand feeding systems that match delivery to appetite. The effects of domestication and captive rearing on feed intake are then considered, together with possible ways of mitigating such effects in fish that are cultured for release.

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The feeding behaviour of cultured and wild Atlantic salmon, Salmo salar L., in the Louvenga River, Kola Peninsula, Russia

Cited by 43 publications

References 29 publications

The biogeography of the atlantic salmon (Salmo salar) gut microbiome

The biogeography of the atlantic salmon (Salmo salar) gut microbiome

Not all lineages are equally invasive: genetic origin and life-history in Atlantic salmon and brown trout acclimated to the Southern Hemisphere

Appetite and Feed Intake

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