Topical and trophic relationships in a boring polychaete–scallop association: fatty acid biomarker approach

Silina, Alla V.; Zhukova, Natalia V.

doi:10.3354/meps08189

Cited by 17 publications

(18 citation statements)

References 40 publications

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“…FA trophic markers have long been recognized as efficient tools in studies of marine food webs (Sargent et al 1989, Budge et al 2002, 2006, Dalsgaard et al 2003. Recent studies have demonstrated that FAs can be successfully used to elucidate feeding ecology and trophic relationships of marine fish (Drazen et al 2009, Stowasser et al 2009) and invertebrates (Silina & Zhukova 2009, Spilmont et al 2009). However, northern/temperate and abyssal marine ecosystems have been the focus of most research efforts, and FA data regarding trophic interactions in tropical marine ecosystems are scarce (reviewed by Dalsgaard et al 2003).…”

Section: Discussionmentioning

confidence: 99%

Characterization of forage fish and invertebrates in the Northwestern Hawaiian Islands using fatty acid signatures: species and ecological groups

Piché¹,

Iverson²,

Parrish³

et al. 2010

Mar. Ecol. Prog. Ser.

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Section: Discussionmentioning

confidence: 99%

Characterization of forage fish and invertebrates in the Northwestern Hawaiian Islands using fatty acid signatures: species and ecological groups

Piché¹,

Iverson²,

Parrish³

et al. 2010

Mar. Ecol. Prog. Ser.

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“…Starvation of Yeso scallop in wild populations from the study area has never been mentioned in a literature. This scallop feeds on a mixed, but diatom-dominated phytoplankton diet (Silina & Zhukova, 2009). According to some estimates, the diatom genera Thalassiosira, Coscinodiscus, Pseudo-nitzschia, Chaetoceros, Thalassionema, Rhizosolenia, and Skeletonema account for about 60–90% of the total phytoplankton biomass in the study area.…”

Section: Discussionmentioning

confidence: 99%

Sex change in scallop Patinopecten yessoensis: response to population composition?

Silina

2018

PeerJ

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Sex structure is very labile between populations and specific for each population because it is a result of genetic, ontogenetic and biocenotic influences on the mollusks. In this study, the age frequency distribution, age-sex structure, and sex ratio were assessed in the wild populations of the Yeso scallop Patinopecten yessoensis (Jay) observed at fifteen sites in the northwestern Sea of Japan (=East Sea). The sex ratio varied between the populations from 0.83:1 to 1.52:1 (males/females), with the mean sex ratio being 1.03 ± 0.05:1. Within a population, the proportions of males and females in term of number differed between age classes. Males were more numerous than females in the younger age classes, and females prevailed over males in the older age classes. It was found that in different scallop populations the sex change occurred at different ages. In the populations that predominantly consisted of young (two- to four-year-old) individuals, males prevailed over females in the age class 2 yr.; the equal male/female proportion was found in the age class 3 yr.; and in older age classes, females prevailed over males. Another pattern was observed in the populations that consisted mainly of middle-aged (five- to six-year-old) individuals. Here, the age-sex ratio became equal at an age of 4–6 years. In the old populations (mainly 6–12-year-olds) the equal male/female proportion was observed at an age of 8–10 years. Thus, the age of sex change was not uniform for the scallop populations. It depended on the age structure of the population and, thus, was socially controlled. The greater number of females in the older age classes suggests a protandric sex change.

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“…Спектр питания камчатского краба в губе Дальнезеленецкая довольно широк (Павлова, 2008; Дворецкий, 2012а): он включает более 40 видов донных беспозвоночных, среди которых наиболее часто встречаются двустворчатые и брюхоногие моллюски, морские ежи, морские звезды, офиуры, ракообразные и полихеты. Исследования биохимического состава донных животных показали, что содержание жирных кислот сильно варьирует в зависимости от таксономического статуса объекта (Howell et al, 2003;Drazen et al, 2008;Silina, Zhukova, 2009). Например, концентрация ДГК в тканях ракообразных и иглокожих обычно выше, чем в тканях полихет (Howell et al, 2003;Drazen et al, 2008), а концентрация арахидоновой кислоты у моллюсков почти в три раза выше, чем у полихет (Silina, Zhukova, 2009).…”

Section: результаты и обсуждениеunclassified

“…Исследования биохимического состава донных животных показали, что содержание жирных кислот сильно варьирует в зависимости от таксономического статуса объекта (Howell et al, 2003;Drazen et al, 2008;Silina, Zhukova, 2009). Например, концентрация ДГК в тканях ракообразных и иглокожих обычно выше, чем в тканях полихет (Howell et al, 2003;Drazen et al, 2008), а концентрация арахидоновой кислоты у моллюсков почти в три раза выше, чем у полихет (Silina, Zhukova, 2009). Таким образом, можно с высокой долей вероятности утверждать, что основную роль в изменчивости жирнокислотного состава гемолимфы отдельных особей краба имеют не физиологические параметры животных, а то, какие объекты были употреблены ими в пищу.…”

Section: результаты и обсуждениеunclassified

Fatty Acids in the Barents Sea Red King Crab Hemolymph

Dvoretsky

Бичкаева²,

Baranova³

2017

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Поступила в редакцию 02.02.2017 г. Проведено исследование жирнокислотного состава гемолимфы камчатского краба Баренцева моря. Основную его долю составили полиненасыщенные жирные кислоты, на втором месте по встречаемости были насыщенные жирные кислоты, на третьем-мононенасыщенные жирные кислоты. Проведено сравнение полученных результатов с литературными данными. Показано, что размер, пол, стадия линьки, травмированность и стадия зрелости икры (у самок) не влияли на концентрацию жирных кислот в гемолимфе. Ключевые слова: камчатский краб, Баренцево море, гемолимфа, жирные кислоты.

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Topical and trophic relationships in a boring polychaete–scallop association: fatty acid biomarker approach

Cited by 17 publications

References 40 publications

Characterization of forage fish and invertebrates in the Northwestern Hawaiian Islands using fatty acid signatures: species and ecological groups

Characterization of forage fish and invertebrates in the Northwestern Hawaiian Islands using fatty acid signatures: species and ecological groups

Sex change in scallop Patinopecten yessoensis: response to population composition?

Fatty Acids in the Barents Sea Red King Crab Hemolymph

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