Effect of Hydrogen Sulfide Loading on the Activity of Energy Metabolism Enzymes and the Adenylate System in Tissues of the Anadara kagoshimensis Clam

Species with a high resistance to hypoxia are usually characterized by an increased H 2 S tolerance of hydrogen sulfide; however, high anaerobic potential cannot be the only explanation for survival in an environment with elevated concentrations of sulfides. The activity of oxidoreductases, as well...

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Published inInland water biology Vol. 15; no. 5; pp. 632 - 640
Main Authors Soldatov, A. A., Golovina, I. V., Kolesnikova, E. E., Sysoeva, I. V., Sysoev, A. A.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 01.10.2022
Springer Nature B.V
Subjects
Anadara kagoshimensis
Anaerobic processes
Anoxia
Aquaria
Aquarium fishes
ATP
Biodiversity
Biomedical and Life Sciences
Body height
Clams
Contamination
Dehydrogenase
Dehydrogenases
Ecological Physiology and Biochemistry of Hydrobionts
Energy charge
Energy metabolism
Exposure
Freshwater & Marine Ecology
Geoecology/Natural Processes
High resistance
Hydrogen
Hydrogen sulfide
Hydrogen sulphide
Hypoxia
L-Lactate dehydrogenase
Lactate
Lactate dehydrogenase
Lactic acid
Life Sciences
Malate dehydrogenase
Metabolism
Mollusks
Oxidoreductases
Sodium
Sodium sulfide
Sulphides
Survival
Tissue
Tissues
lactate dehydrogenase
clams
hydrogen sulfide
malate dehydrogenase
Black Sea
adenylate system
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Summary:Species with a high resistance to hypoxia are usually characterized by an increased H 2 S tolerance of hydrogen sulfide; however, high anaerobic potential cannot be the only explanation for survival in an environment with elevated concentrations of sulfides. The activity of oxidoreductases, as well as parameters of adenylate system were studied in the tissues of hypoxia/anoxia-tolerant clam Anadara kagoshimensis (Tokunaga, 1906) under conditions of experimental H 2 S loading (HSL). Adult specimens with a shell height of 26–38 mm are used. The control group of clams is kept in an aquarium with an oxygen concentration of 7.0–7.1 mg/L (normoxia). The experimental group is exposed to the effect of HSL created by dissolving sodium sulfide (H 2 S donor) in water to a final concentration of 6 mg S 2– /L; exposure time is 24 h. After the first day of the experiment, the level of O 2 in water is 1.8 mg/L and there is no hydrogen sulfide. Some of the clams are exposed to repeated hydrogen sulfide loading (second day of the experiment), and Na 2 S is introduced to a final concentration of 9 mg S 2– /L; by the end of the second day, 1.9 mg S 2– /L and trace concentration of O 2 (0.03 mg/L) are registered. In the first days of HSL, a high activity of malate dehydrogenase (MDH) against the background of a significant suppression of the activity of lactate dehydrogenase (LDH) and an increase in the values of MDH/LDG index persists; this reflects a strengthening of anaerobic processes in the tissues of anadara with relatively high concentrations of О 2 in water (1.8 mg/L). After the second day of HSL, the activity of oxidoreductases in the clam tissues does not change when compared with the first day; however, the value of adenylate energy charge (AEC) persists against the background of a relative decrease in [ATP]. The retention of AEC indicates the ability of the anadara to exist under conditions of hydrogen sulfide contamination and acute forms of hypoxia/anoxia.
ISSN:1995-0829
1995-0837
DOI:10.1134/S1995082922050194