for subsequent analyses. Aliquots o

for subsequent analyses. Aliquots of the combined homogenates containing
a total of 6 μg of branchial protein were added to 1× NuPAGE
LDS Sample Buffer (Life Technologies Australia, Mulgrave, Victoria,
Australia) and then denatured at 70 °C for 10 min before being loaded
in triplicate into 4–12% Bis–Tris gels (Novex, Life Technologies
Australia) and electrophoresed at 200 V for 45 min (XCell SureLock®
Mini, Life Technologies Australia). Samples were then transferred from
the gels to 0.45 μm Invitrolon PVDF membranes at 35 V for 90 min in
an XCell II™ Blot Module (Life Technologies Australia). Membranes
were blocked with 5% skim milk in TBST and then incubated in primary
antibody (αRB1 1:1000 in TBST) for 60 min at room temperature. A
biotinylated goat anti-rabbit secondary antibody (1:2000, Antibodies
Australia) was then applied to membranes for 60 min at room
temperature. A HRP-streptavidin conjugate (1:1000 in TBST; Vector
Laboratories, USA) was added to themembranes for 30min followed
by the chromagen 3,3′-Diaminobenzidine (DAB). Membranes were
washed and dried and digitised using a Canon flatbed scanner.
Densitometric analysis of bands was conducted using Quantity One
software (Bio-Rad, Gladesville, NSW, Australia).
3. Statistics
All data are presented as means ± the standard error of the mean
(SE). Plasma osmolality, solute concentrations and tissue-specific NKA
activity were analysed by one-way ANOVA and pairwise post hoc t-tests
(Holm adjusted alpha level). Rectal gland masses were compared
across treatments using ANCOVA with body mass as the co-variate.
Within salinity treatments, plasma osmolality and environmental
osmolality were compared using one-sample t-tests. All analyses
were run using R (R Core Team, 2013).
4. Results
4.1. Haematocrit and plasma solute concentrations
HCT did not show significant variation between 25‰(11.18±2.13%),
34‰(13.95 ± 0.65%) and 40‰ (15.01 ± 1.2%) acclimated C. punctatum
(ANOVA F2, 12=1.57, P = 0.25; Table 2). Environmental salinity significantly
influenced plasma osmolality (ANOVA F2, 12 = 369.9, P =
1.65e−11; Fig. 1B) with osmolality of animals acclimated to 40‰
(1153 ± 6 mOsm kg−1) significantly higher than sharks acclimated to
either 25‰ (787 ± 6 mOsm kg−1) or 34‰ (1019 ± 10 mOsm kg−1)
(P=1.6e−11 and P=3.5e−7, respectively). Plasma osmolality of sharks
in the 25‰ treatment was also significantly lower than those from the
34‰ group (P =6.5e−10). Sharks maintained plasma osmolalities that
were either isosmotic with the environment (34‰) or higher than the
environment (25‰ and 40‰) (Fig. 1). Acclimation salinity significantly
affected the concentration of Na+, Cl− and urea in the plasma (ANOVA,
Na+: F2,12 = 18.91, P = 1.95 e−4; Cl−: F2,12 = 8.5, P = 0.005; urea:
F2,12 = 37.3, P = 7.08e−6; Table 2). In all cases, ion and urea concentrations
were highest in the 40‰ treatment and lowest in the 25‰
treatment. A significant effect of salinity on K+ ion concentration within
the plasma was not observed (ANOVA F2, 12 = 0.94, P = 0.42; Table 2).
4.2. Branchial and rectal gland NKA activity
There was no effect of salinity on the mass of the rectal gland after
correcting for the effect of body mass (ANCOVA, F(2, 11) = 0.1322,
P = 0.8775). There was no significant effect of environmental salinity
on the specific activity of the enzyme NKA in either rectal gland
(ANOVA F2, 12 = 0.223, P = 0.80; Fig. 2A) or branchial tissue (ANOVA
F2, 12 = 1.57, P = 0.248, Fig. 2B). In all treatments, NKA activity was
almost ten-fold higher in the rectal gland relative to the gills.