Utilization of Different Macroalgae by Sea Cucumber Apostichopus Japonicus Revealed by Carbon Stable Isotope Analysis

Utilization of Different Macroalgae by Sea Cucumber Apostichopus Japonicus Revealed by Carbon Stable Isotope Analysis

Vol. 8: 171–178, 2016 AQUACULTURE ENVIRONMENT INTERACTIONS Published March 30 doi: 10.3354/aei00173 Aquacult Environ Interact OPENPEN ACCESSCCESS Utilization of different macroalgae by sea cucumber Apostichopus japonicus revealed by carbon stable isotope analysis Bin Wen1,2, Qin-Feng Gao1,2,*, Shuang-Lin Dong1,2, Yi-Ran Hou1,2, Hai-Bo Yu1,2 1Key Laboratory of Mariculture, Ministry of Education, Ocean University of China, Qingdao, Shandong Province 266003, PR China 2Function Laboratory for Marine Fisheries Science and Food Production Processes, Qingdao National Laboratory for Marine Science and Technology, Qingdao, Shandong Province 266003, PR China ABSTRACT: Understanding the feeding habit of sea cucumber Apostichopus japonicus (Selenka) is crucial for improving aquaculture techniques of this commercially important species. In the present study, carbon stable isotopes were used as trophic tracers to investigate the uptake of dif- ferent macroalgae, including brown alga Sargassum muticum, red alga Gracilaria lemaneiformis and green alga Ulva lactuca by A. japonicus. A 70 d experiment was conducted to examine the carbon isotopic signatures of A. japonicus feeding on 6 different types of diets containing either pure powder of a single alga species or mixtures of 2 algae species. After the feeding trial, carbon isotope ratios (δ13C) of A. japonicus showed significant changes and reflected the isotopic compo- sitions of corresponding diets. An isotope mixing model revealed the dietary preferences of A. japonicus between the 3 species of macroalgae, suggesting that green alga U. lactuca was the preferentially utilized food source of A. japonicus, followed by brown alga S. muticum. A. japoni- cus tended to reject red alga G. lemaneiformis in the presence of multiple macroalgae choices. Moreover, the specific growth rates of A. japonicus fed on S. muticum and U. lactuca were similar, but were both significantly higher than those fed on G. lemaneiformis, indicating the direct link between the feeding preferences and growth performance of A. japonicus. KEY WORDS: Apostichopus japonicus · Macroalga · Stable isotope · Growth INTRODUCTION effectively accelerate the degradation of organic matter and enhance the transfer of seagrass-derived Sea cucumbers, belonging to the phylum Echino- organic matter to sediments (Liu et al. 2013, Costa et dermata and class Holothuroidea, are distributed al. 2014). Besides the ecological role in nutrient recy- worldwide in marine habitats, from shallow to deep cling, several sea cucumber species, including Apos- seas. As deposit feeders, these organisms actively tichopus japonicus, are rich in a variety of bioactive select organic-rich particles from the upper millime- compounds with nutritional and medicinal values ters of sediments and promote bioturbation, thus (Aydın et al. 2011, Bordbar et al. 2011). In response playing an important role in detritus food chains increasing demand, an extensive trade in A. japoni- (Yingst 1976, Uthicke 1999, Michio et al. 2003, Hud- cus has developed and this species is widely cultured son et al. 2005, Slater & Jeffs 2010, Slater et al. 2011). in northern China, Japan, Korea and Russia (Chen Moreover, in seagrass ecosystems, holothurians can 2004, Toral-Granda et al. 2008). A better understand- © The authors 2016. Open Access under Creative Commons by *Corresponding author: [email protected] Attribution Licence. Use, distribution and reproduction are un - restricted. Authors and original publication must be credited. Publisher: Inter-Research · www.int-res.com 172 Aquacult Environ Interact 8: 171–178, 2016 ing of the feeding ecology and physiology of A. months, depending on tissue-specific turnover rates japonicus will provide insights into the vital role they (MacAvoy et al. 2001, Phillips & Eldridge 2006, play in nutrient recycling in benthic environments Logan & Lutcavage 2010). Moreover, the develop- and crucial information for improving the aquacul- ment of mixing models allows us to estimate the ture techniques of this species (Uthicke 2001, Slater relative contributions of potential resources to the et al. 2011, Zamora & Jeffs 2011). consumer’s food absorption (Phillips & Koch 2002, Deposit-feeding A. japonicus ingest sedimentary Phillips & Gregg 2003). organic matter, mainly composed of detritus from Simultaneous provision of various food resources is macroalgae to seagrass, decayed animals and other an effective way to examine the feeding selectivity of microorganisms such as benthic diatoms, bacteria mobile sea cucumbers (Uthicke & Karez 1999). In this and protozoa (Zhang et al. 1995). Previous studies study, 3 species of macroalgae, including brown alga have demonstrated that detritus derived from macro- Sargassum muticum, red alga Gracilaria lemanei - algae is the major food source of A. japonicus (Sun et formis and green alga Ulva lactuca were mixed with al. 2013). However, in eelgrass-rich meadows, de - each other as diets to feed A. japonicus. The objec- cayed eelgrass debris such as Zostera marina can be tives of the present study were to compare the food an important food source for A. japonicus (Liu et al. quality of the 3 macroalgal species and to quantify 2013). Many other sea cucumber species including the relative contributions of different macroalgae to Stichopus chloronotus, S. tremulus and Mesothuria the food uptake of A. japonicas. The subsequent intestinalis also tend to select sediments containing effects of food preferences on the growth perform- high macroalgal biomass (Uthicke & Karez 1999, ance of A. japonicus were evaluated to provide scien- Hudson et al. 2005). Different basal food resources, tific evidence for optimizing the ingredients of artifi- e.g. brown, red and green algae, generally have dis- cial feed used in A. japonicus farming. tinctive biochemical compositions and consequently different nutritional values and food quality, which could po tentially influence the feeding selectivity of MATERIALS AND METHODS consumers (Danovaro et al. 2001, Adin & Riera 2003, Jormalainen et al. 2005, Rodil et al. 2008, Duarte et Experimental diets al. 2010). Although the biology of A. japonicus has been studied for several decades, research efforts on Three macroalgal species, including brown alga the feeding habits and food preferences are rela- Sargassum muticum, red alga Gracilaria lemanei - tively scarce to date (Gao et al. 2011, Sun et al. 2013). formis and green alga Ulva lactuca were used as feed Utilization of different food resources by aquatic ingredients in the experiment. Dried macroalgae animals can be directly assessed by stomach content were obtained from Qingdao Great Seven Biotech. analysis. However, this traditional approach is often Six types of diets were prepared for Apostichopus destructive for larger animals and is not feasible for japonicus (Selenka) containing the ingredient of smaller organisms, particularly for A. japonicus or either pure powder of a single alga species or mix- other aquatic invertebrates due to the small size and tures of 2 algae species, i.e. single S. muticum (S), G. the digestive damage caused to the food particles lemaneiformis (G) and U. lactuca (U), and mixtures (Galloway et al. 2015, Gao et al. 2011). More impor- (1:1) of S. muticum and G. lemaneiformis (SG), S. tantly, gut content analysis generally only provides a muticum and U. lactuca (SU), and G. lemaneiformis snapshot of recently ingested food and may be and U. lactuca (GU). The macroalgae were ground biased towards non-digestible food items (Bowen & into fine powder through a 150 µm mesh, then well Iverson 2013, Galloway et al. 2015), thus making it mixed before being pelletized with a feed processing difficult to distinguish the contributions of various machine and stored at 4°C for future use. potential food sources. More recently, stable isotope analysis of carbon and nitrogen has been used as a powerful tool to determine the food sources and Experiment and sample collection feeding selectivity, trophic positions and movement patterns of both aquatic and terrestrial organisms The experiment was conducted at the laboratory of (Peterson & Fry 1987, Hobson 1999, Adin & Riera Qingdao National Ocean Scientific Research Center, 2003, Gao et al. 2006, Boecklen et al. 2011). Stable Ocean University of China. A. japonicus juveniles isotope analysis generally integrates diet information were collected from a local sea cucumber farm and over an extended time period, typically weeks to acclimatized for 14 d before the start of the experi- Wen et al.: Analysis of sea cucumber diets 173 ment. After 48 h starvation, a total of 108 juvenile A. For diet groups SG, SU and GU, a 2-source concen- japonicus with initial body weights of 5.57 ± 0.11 g tration-weighted isotope mixing model was used to were randomly distributed into 18 glass aquaria (50 × evaluate the contribution of each algal ingredient to 40 × 40 cm) in each of which 6 individuals were cul- the food uptake of A. japonicus (Phillips & Koch 2002): tured. The 18 aquaria were further divided into 6 13 13 13 13 groups with 3 replicates for each group. A. japonicus (δ C’X −δ CM)[C]XfX,B + (δ C’Y −δ CM)[C]YfY,B = 0 (2) individuals in each of the 6 groups were fed with one of the 6 diets as described above. Prior to the experi- where fX,B and fY,B represent the fractions of assimi- ment, 10 additional specimens were stored at −80°C lated biomass (B) of sources X, Y, respectively, in the for the initial carbon stable isotope analysis. mixture M, therefore fX,B + fY,B = 1. [C]X and [C]Y rep- During the following 70 d feeding experiment, the resent the carbon concentrations in food sources X, A. japonicus were fed once a day at 15:00 h with a Y, respectively. Isotopic signatures for the sources daily ration of 5% body weight. Water temperature were corrected for trophic fractionation as desig- was maintained at 16.5 ± 0.5°C, salinity ranged from nated by the prime symbol (‘). Average fractionation 29 to 31, aeration was provided continuously, dis- effects of 1‰ for carbon isotope were used to correct solved oxygen was >6.0 mg l−1.

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