Балл 0
Учитывается оригинальная версия переводной публикации
КБПР (данная функция работает в тестовом режиме) 0.12
Количество соавторов публикации - 2
Публикации в изданиях из списка ВАК, не входящие в другие пункты (WoS,Scopus,RSCI), K=0.12
Публикации в изданиях из списка ВАК, не входящие в другие пункты (WoS,Scopus,RSCI), K=0.12
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Ануфриева Е. В.: количество аффилиаций - 1, вклад в КБПР публикации:
формула: K/(Nсоавторов*Nаффил) = 0.12/(2*1) = 0.06 -
Шадрин Н. В.: количество аффилиаций - 1, вклад в КБПР публикации:
формула: K/(Nсоавторов*Nаффил) = 0.12/(2*1) = 0.06
Статья в периодическом издании
General Patterns of Salinity Influence on the Energy Balance of Aquatic Animals in Hypersaline Environment
| Перевод Оригинальная статья: Общие закономерности влияния солености на энергетический баланс водных животных в гиперсоленой среде // Журнал общей биологии. 2022. Т. 83, № 5. С. 369-379 |
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| DOI | https://doi.org/10.1134/S207908642305002X |
|---|---|
| Язык | Английский |
| Журнал | Biology Bulletin Reviews ISSN: 2079-0864; Онлайн ISSN: 2079-0872 |
| Год | 2023 |
| Выходные данные | Том: 13, Номер: 5, Страницы: 420-430 |
| Авторы | |
| Даты |
Поступила в редакцию: 24.06.2022 После доработки 08.09.2022 Принята к публикации: 19.09.2022 Опубликована: 22.09.2023 |
| Абстракт | The energy balance approach based on the principles of thermodynamics makes it possible only to outline the area of the possible and to cut off what cannot be. It is widely used in hydrobiology/ecology to describe ecosystems but very rarely to understand certain empirically found patterns. In the article, on the basis of the generalization and analysis of our own and published data, several empirical generalizations have been made concerning the effect of salinity in the hypersaline range from 35 to 300 g/L on animals, which were analyzed using the energy balance approach. According to the type of osmoadaptive mechanisms, animals are divided into active osmoregulators of salt concentration in body fluids and osmoconformers with osmoadaptation performed inside the cells (the accumulation of osmolytic substances) as in unicellular organisms. Osmoconformer animals are able not only to synthesize different types of osmolytes per se but also to use osmolytes of consumed primary producers or dissolved organic matter. With an increase in salinity above the optimum for both types, there is an increase in energy expenditure for the operation of these mechanisms. The upper limit of halotolerance in osmoconformers can be primarily determined by the presence of available osmolytes in the environment rather than by physiological characteristics of a species. The increase in salinity, in proportion to the increased viscosity of solution, is accompanied by an increase in the cost of movement for all animals. Hence, the costs of movement will tend to the maximum possible, sharply limiting the possibilities of locomotor activity. This reduces the possibility of obtaining the necessary diet. Thus, empirical generalization is as follows: as salinity increases above the optimal level, the total metabolic costs will increase and the resulting diet will decrease. The analysis of this generalization based on the energy balance approach leads to certain conclusions: (1) the possible definitive size will decrease with increasing salinity, as is observed in nature and in experiments; (2) the higher the concentration of food, the less pronounced is this effect; (3) a decrease in body weight allows a species to exist in wider ranges of salinity and food concentration. This, first of all, can explain the fact that an increase in salinity and other unfavorable/stress conditions result in “dropping out” of large-sized animal species from the community in the first place, as is observed in nature. The energy balance approach can be used to understand the revealed empirical patterns. At the same time, it only outlines the areas of the possible and defined the trends, not to mention specific realizations of those possibilities and their mechanisms. It cannot provide understanding of the uniqueness of specific complex processes and systems. |
| Сведения о финансировании, указанные в публикации | This work was supported by the State Assignment for the Federal Research Center of the Institute of Biology of the Southern Seas “Study of Peculiarities of the Structure and Dynamics of Ecosystems of Salt Lakes and Lagoons under the Conditions of Climate Change and Anthropogenic Load for Creating Scientific Bases for their Rational Use” (no. 121041500203-3). |
| URL | https://link.springer.com/article/10.1134/S207908642305002X |
| Дополнительные сведения | |
Запись создана: 22-09-2023 17:21
Последнее изменение: 22-09-2023 17:22
Библиографическая ссылка:
Anufriieva E. V., Shadrin N. V. General Patterns of Salinity Influence on the Energy Balance of Aquatic Animals in Hypersaline Environment // Biology Bulletin Reviews. 2023. Vol. 13, no. 5. P. 420-430. https://doi.org/10.1134/S207908642305002X
[Перевод]
Anufriieva E. V., Shadrin N. V. General Patterns of Salinity Influence on the Energy Balance of Aquatic Animals in Hypersaline Environment // Biology Bulletin Reviews. 2023. Vol. 13, no. 5. P. 420-430. https://doi.org/10.1134/S207908642305002X
[Перевод]
Экспертное заключение: № 331, 2022
Индексация на момент включения в базу:
Web of Science
Web of Science
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В публикации указано госзадание:
№ 121041500203-3 «Изучение особенностей структуры и динамики экосистем соленых озер и лагун в условиях климатической изменчивости и антропогенной нагрузки для создания научных основ их рационального использования» (предыдущий номер АААА-А19-119100790153-3)