Materials and methods

Immature H. bleekeri were obtained from an inshore set net (fixed at a depth of ~30 m; temperature was roughly estimated as 16°C using FRA-ROMS II) in southern Hokkaido in October 2016, and transported using a 500 litre tank (Live fish tank 500; Suiko) filled with fresh seawater saturated with O₂ to the Graduate School of Fisheries Science, Hokkaido University. The ambient sea surface temperature at capture was 19.2°C when we hauled a net containing squid onto the boat. Rearing experiments were performed by holding the squid in one of three 1000 litre circular FRP tanks with closed filtering systems and natural seawater pumped from the Kumaishi coast of Hokkaido (salinity 34%). The inner wall of each tank was painted with vertical black stripes to decrease the likelihood of injuries through squid colliding with the wall. A 12:12 h photoperiod was maintained using white fluorescent tubes during the day 06:00–18:00 h.

After five days of acclimation to the captive conditions, squid were reared at three constant temperatures of 12, 14 and 16°C. Temperature was gradually adjusted to that assigned to each tank over 24 h, controlled by electric coolers and heaters with thermostats, and monitored daily (Table 1). Squid were fed fillets of jack mackerel, Trachurus japonicus, once daily. There were 16, 12 and 21 individuals at 12, 14 and 16°C, respectively, of which 11, 10 and 18 individuals survived longer than 7 days. At the end of the experiments, all surviving individuals were euthanized under anaesthesia with 5% ethanol and stored in a freezer for later processing. All procedures performed in the present study followed the ethical standards of the Life Science Research Ethics and Safety Committee of the University of Tokyo and the animal experiments were approved by the committee.

Table 1. Growth rate and statolith Sr/Ca ratio for Heterololigo bleekeri reared under constant temperature

Among the 39 individuals maintained in tanks longer than 7 days, only 29 individuals showed readable growth rings at the rostrum (i.e. the longitudinal edge of a statolith) and thus were subjected to the following analysis (12°C, N = 9; 14°C, N = 9; 16°C, N = 11; Table 1). After thawing specimens, mantle length was measured and both the left and right statoliths were removed from each individual. Each statolith was temporarily glued onto a glass slide with thermoplastic adhesive (Crystalbond 509-1; Aremco) and the convex side was ground with SiC Foil (grit #1000, #2000, #4000 [=FEPA P1200, P2400, P4000, respectively]; Struers) on a polishing wheel (RotoPol-35; Struers) to approach the core. After detaching the statolith from the glass slide, the flattened surface was embedded in epoxy resin (EpoFix; Struers) and then mounted on another glass slide in an inverted manner. The concave surface was ground with SiC Foil (grit #1000, #2000, #4000 [=FEPA P1200, P2400, P4000, respectively]; Struers) to expose the core, and then buffed with an active oxide polishing suspension (OP-S suspension, 0.25 μm; Struers) on a polishing wheel fitted with a semi-automatic specimen mover (MD-Chem and RotoPol-35/PdM-Force-20; Struers). Daily rings were counted using a system consisting of a light microscope with 50–1000 × magnification, a couple-charged device (CCD) camera, and a computer-controlled image analyser (Jiseki 8, Ratoc System Engineering Company; Figure 1A). The aim of this procedure was to identify the region precipitated during the experimental period and to estimate mean statolith growth rates from daily increments of the statolith diameter (see Jackson, Reference Jackson2004 for the daily periodicity of growth rings). Individual age at the end of the experiment was also indicated in Table 1.

Fig. 1. The rostrum of a statolith extracted from an immature Heterololigo bleekeri (7th individual at 14°C in Table 1). (A) Light photomicrograph of ground surface (scale bar: 20 μm). (B) The corresponding SEM image with 10 beamed spots (scale bar: 20 μm).

The glass slide with a statolith attached was cleaned in an ultrasonic bath, rinsed for 1 min with 99% ethanol, for 1 min with deionized water, and then dried by placing in a vacuum desiccator (at 0.1 atm) at room temperature for 24 h. The upper surface was coated with platinum-palladium (60 s) in an ion-beam sputter coater (Hitachi E-1030) to enhance electrical conductivity. Statolith elemental composition was obtained using a JEOL JXA-8230 electron probe microanalyser (EPMA) at the Atmosphere Ocean Research Institute, University of Tokyo. The wavelength-dispersive spectrometry (WDS) method was used to measure calcium (Ca) and strontium (Sr) concentrations in the rostrum region formed during the experimental period. Exposure times were set at 10 s for peak measurements and 5 s for background measurements with an accelerating voltage of 15 kV and a beam current of 15 nA. Strontium titanate (SrTiO₃) and wollastonite (CaSiO₃) were used as standards for the ZAF correction procedure.

In the WDS analysis, electron beams measuring 3 μm in diameter were focused on a line with 3 μm intervals. Ten points were beamed along the longest growth axis of a statolith if the rostrum portion formed during the experimental period had enough length; otherwise, 10 points were divided into multiple lines drawn in parallel (Figure 1B). After polishing the statolith surface with the OP-S suspension for several seconds, the 10-points measurement was conducted again. By repeating this process, a total of 40 points of Sr/Ca values was collected from each statolith. A mean Sr/Ca value was calculated from the 40 measurements, and treated as a statistically independent unit in the statistical analysis. Averaging multiple measurements seems necessary for obtaining biologically meaningful information from the WDS approach, because the Sr/Ca value from a single measurement is highly dispersive (σ = 0.39 mmol mol⁻¹). Figure 2 illustrates how the estimated standard error of the mean Sr/Ca depends on the number of replicate observations, which should be inversely proportional to $\sqrt n$ in theory. According to this relationship, we estimated the measurement error of the mean statolith Sr/Ca value obtained from 40 replicate observations to be 0.06 mmol mol⁻¹. Our estimation is based on a premise that the spatial distribution of Sr is homogeneous across the rostrum region we measured, because it is unlikely that a single measurement is precise enough to detect a possible finer-scale spatial variation in Sr/Ca and because the heterogeneity would be successfully averaged out by replicate observations if any.

Fig. 2. The standard error of the mean statolith Sr/Ca as a function of the number of replicate observations (grey solid line). Closed dots indicate the average SE values directly calculated from the measurements.

An ordinary linear regression model was applied to the mean Sr/Ca values to obtain least-squares estimates of the slope and y-intercept against rearing temperature (N = 29; Table 1). Data from both sexes were pooled because the sex ratio of experimental individuals was considerably biased. An F-test was conducted to check the null hypothesis that the regression slope is equal to 0. The ordinary linear regression model assumes that the observation Y_i from the i-th individual (i.e. individual Sr/Ca value) is described by the relationship

(1)$$Y_i = \beta _0 + \beta _1X_i + \epsilon _i\;{\rm and}\;\epsilon _i\sim N( {0, \;\sigma_{\rm E}} ) , \;$$

where β ₀ and β ₁ are parameters to be estimated and X_i is the individual rearing temperature. ϵ_i denotes an individual Sr/Ca deviation from the corresponding expected value, $\hat{\beta }_0 + \hat{\beta }_1X_i$, and is assumed to follow a normal distribution with zero mean and σ _E standard deviation, N(0, σ _E). However, in reality the linear relationship between temperature and Sr/Ca is variable among individuals within a species (e.g. Hayashi et al., Reference Hayashi, Suzuki, Nakamura, Iwase, Ishimura, Iguchi, Sakai, Okai, Inoue, Araoka, Murayama and Kawahata2013). This can be formulated by a random intercept model

(2)$$\eqalign{Y_i = \alpha _i + \beta _1X_i + \epsilon _i\;{\rm with}\;\alpha _i\sim N( {\mu_{\rm \alpha }, \;\sigma_{\rm \alpha }} ) \;{\rm and}\;\epsilon _i\sim N( {0, \;\sigma_{\rm e}} ) , \;$$

if one most optimistically assumes that the slope β ₁ is common across all individuals. Standard deviations for the intercept (σ_α) and pure error (σ _e) cannot be separately estimated using our data, but in a previous study it was implied that the former is much greater than the latter (i.e. σ_α >> σ _e; see Irie & Suzuki, Reference Irie and Suzuki2020). Based on this argument, the 95% pointwise confidence interval at X = X ₀ was estimated using

(3)$$\hat{Y}_0 \pm t( {n-2, \;0.975} ) \left\{{1 + \displaystyle{1 \over n} + \displaystyle{{{( {X_0-\bar{X}} ) }^2} \over {\mathop \sum {( {X_i-\bar{X}} ) }^2}}} \right\}^{1/2}s, \;$$

where $\hat{Y}_0 = \hat{\beta }_0 + \hat{\beta }_1X_0$, and s can be replaced with the estimated residual standard deviation, ${\hat{ \rm \sigma}}_{\rm E}$ (see eq. [3.1.6] in Draper & Smith, Reference Draper and Smith1998). t(n − 2, 0.975) signifies T* satisfying P(T > T*) = 0.975 when a random variable T follows the t-distribution with n − 2 degrees of freedom on which s ² is based. The aim was to calculate the 95% confidence interval for the temperature predicted by applying a Sr/Ca value measured for a new statolith specimen to equation (1). All statistical analyses were conducted in the JMP Pro statistical package (version 13 for Windows; SAS Institute) and Mathematica (version 11.0.1 for Windows; Wolfram Research).

The rearing setup of our experiment is not statistically desirable because multiple individuals are kept in the same tanks, which potentially causes pseudoreplication in the obtained data. However, we were not able to prepare more than three tanks of the size large enough to maintain spear squid, as space in the laboratory was limited. This type of pseudoreplication can be theoretically avoided by sequentially conducting solitary rearing (i.e. keeping each individual in an independent tank), but this causes another type of pseudoreplication by ignoring a time-related factor unless repeated measurements from the same individuals are performed according to the within-subject design. The repeated measures design was not feasible in this study because spear squid are not likely to survive until the second measurement as well as because an unacceptable length of time is required to accomplish the entire experiment. We discussed a potential impact on statolith elemental composition by culturing multiple individuals in the same tank (see Discussion).