Dataset: Temperature-dependence of juvenile Black sea bass growth and lipid accumulation - Experiment 2

Name: Temperature-dependence of juvenile Black sea bass growth and lipid accumulation determined through lab experiments conducted from September 2021 to February 2022 at UConn Avery Point
Published: 2023-07-18
Keywords: Black Sea Bass, range expansion, overwinter, lipids, growth efficiency, weight-specific growth, oceans

Cite This Dataset

DOI:10.26008/1912/bco-dmo.898012.1

Spatial Extent: N:41.3236 E:-72.0019 S:41.3236 W:-72.0019

Temporal Extent: 2021-09-03 - 2022-04-01

Project:

Collaborative research: Understanding the effects of acidification and hypoxia within and across generations in a coastal marine fish (HYPOA)

Principal Investigator:

Hannes Baumann (University of Connecticut, UConn)

Student:

Max D. Zavell (University of Connecticut, UConn)

BCO-DMO Data Manager:

Shannon Rauch (Woods Hole Oceanographic Institution, WHOI BCO-DMO)

Version:

Version Date:

2023-07-18

Restricted:

Validated:

Yes

Current State:

Final no updates expected

Temperature-dependence of juvenile Black sea bass growth and lipid accumulation determined through lab experiments conducted from September 2021 to February 2022 at UConn Avery Point

Abstract:

The northern stock of Black sea bass (BSB, Centropristis striata) has greatly expanded over the past decade, potentially due to warming Northwest Atlantic shelf waters affecting overwintering especially in juveniles. To gather better empirical data we quantified winter growth and lipid accumulation in BSB juveniles from Long Island Sound using two complementing experiments. The data from Experiment 2 are presented here. The data from Experiment 1 are presented in a related dataset (https://www.bco-dmo.org/dataset/897895). Experiment 2 measured the same traits as Experiment 1 but exposed juveniles to a simulated thermal overwinter profile (October - March) with seasonally varying food rations. Monthly individual length growth (GR) and weight-specific growth (SGR) responded in the direction of seasonal food level changes, showing reduced growth in December-February in a 'Winter dip' treatment, but compensatory growth in a 'Winter pulse' treatment. A 6-month consumption average of 1.7% feeding-1 ('Winter pulse') elicited a mean GR of 0.15 millimeters per day (mm d-1) and SGR of 0.55% d-1, whereas juveniles consuming on average 3.8% per feeding ('Winter dip') had significantly faster GR (0.20 mm d-1) and SGR (0.71% d-1). Growth efficiencies ranged between 15-30% and were inversely related to food consumption. In both experiments, juveniles disproportionally accumulated lipid over lean mass, with lipid proportions tripling in Exp2 from 4% at 65 mm to 12% at 120 mm.

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Archival Copy

Version Date	Archive	Persistent Identifier (PID)	Date PID Issued
2023-07-18	Marine Biological Laboratory/Woods Hole Oceanographic Institution Library (MBLWHOI DLA)	10.26008/1912/bco-dmo.898012.1	2023-07-18

Methods & Sampling

Juvenile Black sea bass (BSB) were caught on September 3rd (collection 1) and 21st 2021 (collection 2) via beach seine (30 × 2 meters) in Mumford Cove (41° 19' 25"N, 72° 01 '07"W), a shallow protected bay with extensive eelgrass cover in eastern Long Island Sound, USA.

Experiment 2 quantified juvenile winter growth and lipid accumulation under seasonally varying food and temperature conditions over the course of 182 days (October 1, 2021 to April 1, 2022). Initial total length (TL, mean ± SD = 70.9 ± 5.4 millimeters (mm)) and wet weight (wW, mean ± SD = 4.4 ± 0.9 grams (g)) were determined on briefly anesthetized specimens, followed by randomly distributing 48 juveniles into individual 20-liter (L) rearing containers with mesh-screened holes, an air stone, and a PVC hide. An additional baseline sample (n = 25, mean ± SD TL = 71.4 ± 9.4 mm, wW = 4.7 ± 1.8g) was euthanized and stored at -20° Celsius (C). We then used six 700 L recirculating tanks to each house eight individual BSB rearing containers (mean maximum stocking density = 0.13 kilograms per cubic meter (kg m⁻³). Tanks (n = 2 tanks per treatment; n = 8 containers per tank) were randomly assigned to one of three seasonally varying food treatments (Otohime C1 pellets) designed to simulate three phases of contrasting overwinter food availability for BSB juveniles. The 'Winter dip' treatment was fed 5% body wW 3× weekly during Phase 1 ("Fall": October, November), 2% wW 3× weekly during Phase 2 ("Winter": December – February) and again 5% body wW 3× weekly during Phase 3 ("Spring": March). This was to simulate a scenario of good onshore feeding conditions for juveniles in fall and spring, but poorer feeding conditions at their offshore overwintering habitats. Conversely, our 'Winter pulse' treatment was to simulate poor fall and spring feeding conditions for juveniles onshore by feeding 1% wW 3× weekly during Phase 1 and 3, but 2% wW during Phase 2, thereby simulating the same offshore winter feeding conditions (Fig.2A of Zavell et al. (in review)). Last, we included a 'Constant' treatment as control, which fed 2% wW 3× weekly throughout the entire six months of rearing (Phases 1-3). Food rations were based on both Cotton (2002), who showed no difference in growth at rations of 5 - 7.5% wW, but reduced growth at 2.5% wW and Watanabe et al. (2021) who report ideal feeding rates between 3 – 5% wW. For all treatments, rations were individually recalculated after the 1ˢᵗ of each month, based on re-measured wW and TL on briefly anesthetized fish.

Temperature conditions in Exp2 were recorded in 30 minute intervals using HOBO temperature loggers (Onset MX^®).

Response traits. Initial, monthly (Exp2 only), and final measurements of individual fish (TL, wW) were used to calculate total (final – initial), cumulative (end of month – initial), and/or serial (end of month – start of month) growth (e.g., cumulative and serial DTL for month 2 = TL_d61 – TL_d0and TL_d61 – TL_d31), respectively) and average daily growth rates (growth/days in growth interval). Specific growth rates (SGR; % wW per day) were calculated similarly but used ln(wW) at each time period (e.g., 100*[ln(wW_d61)-ln(wW_d31)]). Growth efficiency (GE, %) was calculated cumulatively (Exp1, Exp2) and monthly (Exp2 only) as the change in body dry weight (DdW_b, g) divided by total food consumed (DF, g) during a given time interval. (In Exp2, three GE values > 100% were excluded as outliers). Q₁₀ values (Exp1) were calculated for GR, SGR, and GE between 6-12°C and 12-19°C.

For each experiment, we also determined the lipid, lean, and ash dry weights of each surviving BSB juvenile and those of the baseline samples. Whole specimens were first transferred to -80°C for one week, then freeze-dried at -50°C for one week and re-measured for whole body dry weight (dW_b, 0.001 g). Dried specimens were then loaded into pre-weighed Alundum medium-porosity extraction thimbles and transferred into a custom-designed Soxhlet apparatus, where they were bathed in petroleum ether for a total of 3.5 hours to extract all metabolically accessible lipids (15-minute cycles of bathing, flushing, and ether replacement). After extraction, thimbles were dried overnight at 60°C and re-weighed to determine DdW, which equaled the total lipid content (dW_Lipid, milligrams (mg)) of each specimen after accounting for any tissue loss during transfer from vial into thimble. Thimbles were then placed in a muffle furnace for 4 hours at 550°C and re-weighed, with DdW during this second step corresponding to a fish's lean mass (dW_Lean, mg), again after accounting for any tissue loss during transfer from vial into thimble. The difference between the final weight and the pre-weighed empty thimble equaled ash (dW_Ash, mg), i.e., the inorganic fraction of each individual.

Data Processing Description

BCO-DMO Processing:
- Imported original file named "BCO-DMO-Source-BSB-Juvenile-Overwintering-V2.xlsx" sheet 3 into the BCO-DMO data system;
- renamed fields to comply with BCO-DMO naming conventions (replaced spaces with underscores);
- converted dates to YYYY-MM-DD format;
- added columns for latitude and longitude in decimal degrees;
- rounded values to 3 decimal places;
- named the final file "898012_v1_bsb_experiment2.csv".

Data Files

File
898012_v1_bsb_experiment2.csv (Comma Separated Values (.csv), 69.14 KB) MD5:0781d9e43cf76b303609fffff7ab48e1 Primary data file for dataset ID 898012, version 1.

More Information about this dataset

Funding Sources

Funding Source	Award Number
NSF Division of Ocean Sciences	OCE-1536336

Deployments

None available yet

Instruments

Automated Larval Fish Rearing System

Supplied Name: Automated Larval Fish Rearing System (ALFiRiS)

Supplied Description:

Instrument Type

Generic Name: Automated Larval Fish Rearing System

Acronym: ALFiRiS

Generic Description:

The Automated Larval Fish Rearing System (ALFiRiS) was self-designed and assembled in the Rankin Lab at the University of Connecticut Avery Point. It consists of a 3 x 3 array of recirculating units (600 liters/150 gallons) that have independent computer-control over their temperature, oxygen, and pH conditions.

The system was designed to sequentially monitor tank conditions via industrial-grade oxygen and pH sensors (Hach) and then control gas solenoids (air, N2, CO2) to maintain and modulate environmental conditions. The system can apply static as well as fluctuating conditions on diel and tidal scales. Computerized temperature control allows simulating heatwaves and other non-static thermal regimes.

More information can be found at https://befel.marinesciences.uconn.edu/alfiris/

Soxhlet extractor

Supplied Name: Custom-designed Soxhlet apparatus for Lipid/Lean analyses

Supplied Description:

Instrument Type

Generic Name: Soxhlet extractor

Generic Description:

A Soxhlet extractor is a piece of laboratory apparatus designed for the extraction of a lipid from a solid material. The solid is placed in a filter paper thimble which is then placed into the main chamber of the Soxhlet extractor. The solvent (heated to reflux) travels into the main chamber and the partially soluble components are slowly transferred to the solvent.

Temperature Logger

Supplied Name: HOBO temperature loggers (Onset)

Supplied Description:

Instrument Type

Generic Name: Temperature Logger

Generic Description:

Records temperature data over a period of time.

Parameters

Date and time formats are described in python strftime() syntax.

Supplied Name	Supplied description	Supplied Units	Standard Name
Site	Site name; Mumford Cove, CT - all fish	unitless	site
Longitude	Longitude of collection site in decimal degrees (negative values = West)	decimal degrees	lon
Latitude	Latitude of collection site in decimal degrees (positive values = North)	decimal degrees	lat
Date_col	Date of juvenile collection in the wild Format: %Y-%m-%d	unitless	date
Species	Name of species (Black Sea Bass - Centropristis striata)	unitless	species
Tank	Experiment Tank (A - F), G represents Baseline Samples	unitless	tank
BSB_ID	ID of each BSB individual	unitless	sample
Group	Experiment 2 OR Baseline (sacrificed at the beginning of the experiment)	unitless	sample_descrip
Treat	Seasonally varying food treatment, either 'Winter dip', 'Winter pulse', or 'Constant' \| 'Baseline' denotes fish sampled at the beginning of the experiment (10/1/21; n=25) for initial lipid analyses. They were NOT reared and therefore have EMPTY fields for experimental parameters	unitless	treatment
Food	Mean realized food ration per feeding, based on offered food, consumed food per week, averaged over whole experiment, values of 3.8% feeding-1 ('Winter dip'), 1.7% feeding-1 ('Winter pulse'), and 2.2% feeding-1 ('Constant')	percent (%) wW per feeding	treatment
Date_sam	Date of repeated length and weight measurments Format: %Y-%m-%d	unitless	date
Exp_Phase	Phase i - iii of the experiment. Phase i was 'Fall' (Oct,Nov), Phase 'ii' was 'Winter' (Dec,Jan,Feb), Phase 'iii' was "Spring (Mar)	unitless	treatment
Month	Month of length and weight measurements	unitless	month
TP	Time Point (values of 1 - 6)	unitless	time_point
TL	Total length at the end of the month	millimeters (mm)	length
TL0	Total length at experiment start	millimeters (mm)	length
DTL	Change in TL from experiment start	millimeters (mm)	length
wW	Wet Weight at the end of the month	grams (g)	weight
wW0	Wet Weight at experiment start	grams (g)	weight
DwW	Change in wet Weight at experiment start	grams (g)	weight
dW_est	Dry weight (estimated from post-mortem wet/dry weight relationship)	grams (g)	weight
dW0	Dry weight at experiment start	grams (g)	weight
DdW	Change in dry weight from experiment start	grams (g)	weight
GR_TP	Growth in TL during month	millimeters (mm)	growth
GR_wW	Growth wW during month	grams (g)	growth
GR_dW	Growth in dW during month	grams (g)	growth
Time	Days of the month	Days	days
GRTL	Growth in TL per day	millimeters per day (mm d-1)	growth
SGRwW	Weight-specific growth per day	percent (%) wW per day	growth
SGRdW	Dry weight-specific growth per day	percent (%) dW per day	growth
Temp	Mean monthly temperature	Degrees Celsius °C	temp
TempSD	Standard deviation of mean monthly temperature	Degrees Celsius °C	temp
DD	Degree days this month	degree-days (°C × days)	days
Consum	Food consumed this month	grams (g)	food_consumption
GE	Gross growth efficiency (dryweight-based)	percent (%)	growth
dW_final	Dry weight measured after freeze-drying the specimen post-experiment	milligrams (mg)	weight
TL_final	Final total length at the end of the experiment	millimeters (mm)	length
Lipid	Lipid content of the specimen	milligrams (mg)	lipids_biota
Lean	Muscle/lean = protein content of the specimen	milligrams (mg)	proteins
Ash	Inorganic = ash content of the specimen	milligrams (mg)	ash
Prop_Lipid	Lipid / dW_final	percent (%)	lipids_biota
Prop_Lean	Lean / dW_final	percent (%)	proteins
Prop_Ash	Ash / dW_final	percent (%)	ash