Effect of salinity on the metabolism and osmoregulation of selected ontogenetic stages of an amazon population of Macrobrachium amazonicum shrimp (Decapoda, Palaemonidae)

Mazzarelli, C C M; Santos, Michelle R.; Amorim, Rafael Vieira; Augusto, Alessandra

doi:10.1590/1519-6984.14413

Cited by 17 publications

(7 citation statements)

References 25 publications

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“…The energy expended in metabolic processes, the total sum of all chemical reactions taking place in an organism, as measured by oxygen consumption, is used for the maintenance of homeostasis, including locomotion, growth, and reproduction (Diaz-Iglesias et al, 2012;McGaw et al, 2013;Mazzarelli et al, 2015). The individual oxygen consumption rate in M. amazonicum is directly related to the size of the animals, and it is higher in the GC1 and GC2 morphotypes ( Table 1).…”

Section: Metabolismmentioning

confidence: 99%

Are there any physiological differences between the male morphotypes of the freshwater shrimp Macrobrachium amazonicum (Heller, 1862) (Caridea: Palaemonidae)?

Augusto

Valenti

2016

Journal of Crustacean Biology

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A comparison was made of the metabolism, nitrogenous excretion, growth, oxidized energy substrate, ingestion rate, and fecal production of the males of three morphotypes (CC, GC1, and GC2) of the palaemonid shrimp Macrobrachium amazonicum (Heller, 1862). The proportion of these morphotypes in the population is fixed, and individuals can change from one type to another (TC to CC, CC to GC1, and GC1 to GC2) to maintain this proportion. The three morphotypes were evaluated for 30 days, during which individuals were fed daily with commercial food. Food debris, feces, and exuviae were collected daily. Oxygen consumption was measured in a closed respirometer, and ammonia excretion was measured by colorimetry. The atomic ratio O:N was used to indicate the predominant energy substrate oxidized. Mass gain (% WW i) was higher in morphotypes CC and GCI (12.7 ± 3.2 and 16.0 ± 3.7%, respectively) than in GC2, in which it was nearly zero (1.9 ± 1.5%). Lost exuviae contained approximately 40% of the energy content of the individuals, and males did not cease feeding as post-molts as reported in some crustaceans. Despite the elevated growth of CC and GC1, the ingestion rates were similar in all morphotypes and corresponded to 3% of the total biomass. It is possible that CC and GC1 channel a higher percentage of ingested energy and nutrients into growth, whereas GC2 channels more energy into other pathways such as reproduction. Whereas the morphotypes CC and GC1 mainly use carbohydrates as their energy substrate, GC2 uses proteins. Given the elevated growth rate of CC and GC1, they appear to preferentially use amino acids in tissue building, whereas GC2 uses these substrates as an energy source. The feces eliminated by the morphotypes were always proportional to the ingestion rate (approximately 2%), suggesting utilization in terms of nutrient absorption was similar for them. Oxygen consumption in specific mass was similar for all three morphotypes (approximately 1.8 μg (mg dw) −1 h −1), and ammonia excretion was approximately 180% higher in GC2 than in the other two morphotypes. These results might reflect the pattern of growth, activity, function in the population, and differences in reproductive behaviour in the morphotypes and could be evidence of a preparation for the subsequent morphotype.

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Section: Metabolismmentioning

confidence: 99%

Are there any physiological differences between the male morphotypes of the freshwater shrimp Macrobrachium amazonicum (Heller, 1862) (Caridea: Palaemonidae)?

Augusto

Valenti

2016

Journal of Crustacean Biology

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“…However, this factor did not influence significantly the abundance of M. surinamicum in this estuary. Mazzarelli et al (2015) verified that zoeae I of M. amazonicum do not alter their metabolism due to the exposition to fresh or brackish water, but metabolism alterations were not followed by changes in free amino acids concentration in zoeae II and V exposed to fresh and brackish water.…”

Section: Discussionmentioning

confidence: 66%

Abundance and spatial-temporal distribution of Macrobrachium surinamicum Holthuis, 1948 (Palaemonidae) in the Amazon estuary, north of Brazil

2016

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Macrobrachium surinamicum is a small shrimp that inhabits rivers of low salinity. It is mainly caught as bycatch in Amazon shrimp Macrobrachium amazonicum fisheries, which is widely exploited by artisanal fisheries for food and economic needs of the riverside population. This study aimed to characterize the spatial and temporal distribution of the freshwater shrimp M. surinamicum in the Guajará Bay and on Mosqueiro Island, correlating the abundance of this species with abiotic factors (temperature and salinity). ResumoMacrobrachium surinamicum é um camarão de pequeno porte que habita a foz de rios e águas de baixa salinidade. Sua captura na Amazônia ocorre principalmente como fauna associada à pesca do camarão-da-Amazônia Macrobrachium amazonicum que é largamente explorado pela pesca artesanal atendendo as necessidades alimentícias e econômicas da comunidade ribeirinha. O presente estudo teve como objetivo caracterizar a distribuição espaço-temporal do camarão dulcícola M. surinamicum na Baía do Guajará e Ilha de Mosqueiro, correlacionando a abundância desta espécie com fatores abióticos (temperatura e salinidade). Os exemplares foram capturados no período de maio/06 a abril/07 em seis locais: Ilha de Mosqueiro (Furo das Marinhas e Porto do Pelé), Distrito de Icoaraci, Ilha do Arapiranga, orla de Belém e Ilha do Combu com armadilhas (matapis). Um total de 361 camarões foi capturado, sendo a maior abundância em dezembro e a menor em julho de 2006. A maior captura foi na Ilha de Arapiranga e a menor na Ilha de Mosqueiro. A abundância diferiu significativamente em dezembro/06 e nenhuma variável estudada teve influência significativa na abundância de M. surinamicum. A Baía do Guajará, especialmente os locais mais abrigados como a Ilha de Arapiranga e do Combu, propiciam o desenvolvimento de M. surinamicum, o que indica que esta espécie tenha preferência para áreas menos antropizadas.Palavras-chave: Crustacea, Decapoda, ecologia, camarão dulcícola.

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“…In addition, penaeid marine shrimps are hyper-hypo-regulators (Péqueux 1995, Freire et al 2008b, as opposed to palaemonid shrimps, which are essentially hyper-regulators, as already mentioned. In the results of an experiment with M. amazonicum at different ontogenetic stages (zoea I, II, V, and IX) exposed to different salinities (0.5, 6, 12 or 18 psu), there was a greater consumption of oxygen at 0.5 psu in the zoea stage V, probably due to the great amounts of energy required for the active transport of salts through the epithelia (Mazzarelli et al 2015). A similar pattern was observed in M. tuxtlaense, an strictly freshwater prawn exposed to a salinity gradient (0,5,10,15,20,25, and 30 psu): higher rates of oxygen consumption in the shrimp M. tuxtlaense were observed at low salinities (0, 5 and 10 psu), to account for hyper-regulation of the osmolality of the hemolymph (Ordiano 2005).…”

Section: Discussionmentioning

confidence: 99%

“…Some palaemonid shrimps exposed to salinity increases, for instance Macrobrachium heterochirus (Wiegmann, 1836) and Macrobrachium potiuna (Müller, 1880), experience a decrease in metabolic rates, while the diadromous Macrobrachium acanthurus (Wiegmann, 1836) and Macrobrachium olfersii (Wiegmann, 1836) experience a peak in their metabolism-salinity curves ("dome-shaped curve") close to their isosmotic point, ~21 psu (Moreira et al 1983). In another diadromous shrimp, Macrobrachium amazonicum (Heller, 1862), oxygen consumption was lower in freshwater than in 18 psu in zoea II, and was higher in freshwater than in 12 and 18 psu in zoea V (Mazzarelli et al 2015). The freshwater shrimp Macrobrachium tuxtlaense Villalobos and Alvarez, 1999, when exposed to increased salinities up to 30 psu, has shown an increase in oxygen consumption in 5 and 10 psu, and a decrease in this parameter in the other salinities, with respect to the control salinity, fresh water (Ordiano et al 2005).…”

Section: Introductionmentioning

confidence: 99%

Oxygen consumption remains stable while ammonia excretion is reduced upon short time exposure to high salinity in Macrobrachium acanthurus (Caridae: Palaemonidae), a recent freshwater colonizer

et al. 2017

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ABSTRACT. Palaemonid shrimps occur in the tropical and temperate regions of South America and the Indo-Pacific, in brackish/freshwater habitats, and marine coastal areas. They form a clade that recently (i.e., ~30 mya) invaded freshwater, and one included genus, Macrobrachium Bate, 1868, is especially successful in limnic habitats. Adult Macrobrachium acanthurus (Wiegmann, 1836) dwell in coastal freshwaters, have diadromous habit, and need brackish water to develop. Thus, they are widely recognized as euryhaline. Here we test how this species responds to a short-term exposure to increased salinity. We hypothesized that abrupt exposure to high salinity would result in reduced gill ventilation/perfusion and decreased oxygen consumption. Shrimps were subjected to control (0 psu) and experimental salinities (10, 20, 30 psu), for four and eight hours (n = 8 in each group). The water in the experimental containers was saturated with oxygen before the beginning of the experiment; aeration was interrupted before placing the shrimp in the experimental container. Dissolved oxygen (DO), ammonia concentration, and pH were measured from the aquaria water, at the start and end of each experiment. After exposure, the shrimp's hemolymph was sampled for lactate and osmolality assays. Muscle tissue was sampled for hydration content (Muscle Water Content, MWC). Oxygen consumption was not reduced and hemolymph lactate did not increase

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Effect of salinity on the metabolism and osmoregulation of selected ontogenetic stages of an amazon population of Macrobrachium amazonicum shrimp (Decapoda, Palaemonidae)

Cited by 17 publications

References 25 publications

Are there any physiological differences between the male morphotypes of the freshwater shrimp Macrobrachium amazonicum (Heller, 1862) (Caridea: Palaemonidae)?

Are there any physiological differences between the male morphotypes of the freshwater shrimp Macrobrachium amazonicum (Heller, 1862) (Caridea: Palaemonidae)?

Abundance and spatial-temporal distribution of Macrobrachium surinamicum Holthuis, 1948 (Palaemonidae) in the Amazon estuary, north of Brazil

Oxygen consumption remains stable while ammonia excretion is reduced upon short time exposure to high salinity in Macrobrachium acanthurus (Caridae: Palaemonidae), a recent freshwater colonizer

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