(Bansemer et al., 2014; Bautista-Te

(Bansemer et al., 2014; Bautista-Teruel and Millamena, 1999; Stone et al., 2013). The abalone industry is relatively new compared to other aquaculturesectorssuchas fin fish, whichhave successfully developed pre-starter, starter, grower and finisher diets for different grow-out stages(NgandRomano,2013;Sarkeretal.,2013).Thereisanincreased demandto introduce multi-diet feeding strategiesfor greenlip abalone byoptimisingthedietaryproteinlevelforeachageclassandwatertemperaturethroughouttheproductioncycle.However,theoptimaldietary protein level for greenlip abalone throughout their whole production cycleisnotclear.Priorto2013,Australianabalonedietswereformulated tocontain~27% crudeprotein(CP)based onagrowthtrialforjuvenile greenlip abalone (0.55–0.94 g) at 20 °C (Coote et al., 2000). Currently however, Australian abalone feed contains 30 to 35% CP as suggested by recent research for greenlip abalone (1.75 g) at 22 °C (Stone et al., 2013), but the authors also reported the optimal dietary protein level is dependent on both age (1 and 2-year old abalone) and water temperature (14, 18 and 22 °C). Further research, focused on the nutritional requirements of greenlip abalone soon after weaning (~6-month old abalone), is required to improve our understanding on feed formulation for juvenile abalone. Inthisstudy,ouraimwastoidentifytheoptimaldietaryCPlevelfor post-weaned greenlip abalone (6-month old) at 14, 17 and 20 °C. On-farm, in land-based facilities throughout southern Australia, the water temperature fluctuates throughout the grow-out period; the watertemperaturesselectedinthecurrentstudyrepresentthetemperature range typically occurring from autumn, through winter, to early summer experienced by post-weaned juvenile greenlip abalone. The nominal dietary CP levels used in this study were 27, 30, 33 and 36%. These levels are considered to be commercially applicable to landbased abalone production in southern Australia. Diets used in this studywereformulatedonadigestibleproteinbasisandcontainedhighlypalatableanddigestibleingredientsatrealisticinclusionlevels,using protein and energy digestibility data reported for greenlip abalone (Fleming et al., 1998; Vandepeer, 2005). Diets were formulated using the “ideal protein concept,” such that the ratio of each essential amino acid to lysine was equal to, or greater than, the soft tissue amino acid values for greenlip abalone (Coote et al., 2000). Diets contained ~3.6% lipid (Dunstan et al., 2000; Van Barneveld et al., 1998), and ~17. 4MJkg−1 crudeand~12.5MJkg−1 digestibleenergylevels.Theresults of this study will contribute towards the development of diets suitable for early weaned abalone at different water temperatures and the formulationofappropriateabalonedietsforeachgrow-outstagethroughouttheabaloneproduction cycle.
2.Methods
2.1. Experimental animals and system
Greenlip abalone (weight 0.91 ± 0.00 g; shell length 19.46 ± 0.02mm;n=864)werepurchasedfromSouthAustralianMariculture (PortLincoln,SouthAustralia,Australia)inApril2013.Priortostocking, abalonewereheldinaflowthroughseawatersystematSouthAustralia Research and Development Institute Aquatic Science Centre (SARDI ASC) (West Beach, South Australia, Australia) for two weeks and fed a commercialdiet (~30%CP; Eyre Peninsula Aquafeed Pty Ltd., Lonsdale, SA, Australia). The experiment was conducted in a photoperiod and temperature controlled laboratory described in Stoneet al. (2013). The photoperiod was 12 h low intensity fluorescent lighting at 3.4 lx: 12 h dark. The air temperature was adjusted based on the incoming water temperature and ranged from 16.0 to 19.3 °C. Three identical culture systems (14, 17 or 20 °C) were supplied with 30 μm sand-filtered, UV treated seawater (Model 025120-2, 120w, Emperor Aquatics, Pottstown, PA, USA). Sixteen 12.5-L blue plastic culture units (Nally IH305, Viscount PlasticsPtyLtd.;39.2×28.8×11.0cm)persystemwereeachsupplied with flow-throughseawater(300mLmin−1).Waterdepthwasheldat
2.5cmusingastandpipewithameshscreen(0.8mm)ontheoutletto retain uneaten feed. Water temperature was held at 14, 17 or 20 °C (±1 °C) throughout the experiment through the use of either immersion heaters (240 V, 3 kw, JQ20; Austin and Cridland, Carlton, NSW, Australia) or chillers (3 hp, 240 V, 50 Hz: Daeil Cooler Co., Ltd., Busan, Korea).
2.2. Stocking
Abalone were gently pried from the substrate using a spatula. Eighteen animals were weighed, measured and stocked into one of four replicate culture units per treatment combination. Animals were acclimated to the system for 16 days and fed their respective diets. After seven days the water temperature was either lowered or raised slowly (1 °C day−1) to the desired water temperatures (14, 17 or 20 °C) and was maintained at these levels (±1 °C) throughout the remainder of the 75 day experiment. Dead abalone during the experiment were measured, weighed, recorded, and replaced with abalone of a similar weight and size that had been held at each respective water temperature and fedthe commercial formulated diet.
2.3. Diets and feeding
Ateachtemperature,animalswerefedwithoneoffourdietaryproteinlevels(27,30,33and36%CP,Table2).Theproximatecomposition of the ingredients was analysed prior to diet formulation. Diets were formulated on a digestible protein and isoenergetic basis, based on data reported for greenlip abalone (Fleming et al., 1998; Vandepeer, 2005). Solvent-extracted soybean meal, de-hulled lupins, casein and fish meal were used as the main dietary protein source, while fish oil and de-hulled lupins were used as the main dietary lipids source. Diets were alsoformulated,using book values, so that the ratio of each essentialaminoacidtolysinewasequalto,orgreaterthanthatanalysed for the soft body tissue of greenlip abalone (Coote et al., 2000). Due to the difficulty in determining the amino acid requirement of abalone (Shiptonetal.,2002),applyingthe“idealproteinconcept”wasconcluded to be an acceptable alternative (Fleming et al., 1996). Diets were cold-pressed into flat pellets (4 × 3 × 2 mm thick) using a commercial pasta machine (La Prestigiosa medium; IPA. Vicenza. Italy). The dry matter leaching loss for each diet was determined in triplicate by submerging the diet (1 g) in seawater (25 mL) at 14, 17 and 20 °C for 16 h. After 16 h, the supernatant was removed, by syringe, and the remaining pellets were dried at 105 °C for 16 h. The dry matter leaching loss for all diets was highest at 20 °C, but was less than 8% dry weight. Abalonewerefedtoexcessoftheirdailyrequirements(4%oftheabalone biomass day−1) at 16:00 h. Feed rates were maintained at these levels throughout the study based on monthly weight checks. Tanks were cleaned and uneaten feed was collected by sieving the entire tank contents through a fine mesh at 08:30 h and stored at −20 °C, andwaslaterdriedat105 °Cfor16h.Dailyfeedconsumptionwasestimated by the difference between feed offered and uneaten feed in dry weight. The proportion of uneaten feed lost between 08:30 to 16:00 h, from leaching and by sieving the entire tank contents through a fine meshwithoutanimalsinthetank,attherespectivewatertemperatures, wasusedasacorrectionfactortocalculatetheapparentfeedconsumption rate.
2.4. Biochemical and water quality analysis
At the commencement of the experiment, the soft tissue of 50 animals (n = 4 replicates) were collected, shucked and stored at−20 °C to analyse the initial soft tissue proximate composition. At the conclusion of the experiment, 10 abalone from each tank were collected, shucked and stored at−20 °C. The abalone were later pooled for each tank for the analysis of soft tissue proximate composition. The proximatecompositionanalyses of ingredients,diets, and wholebody tissue
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