Effects of reduced salinity
on the biochemical composition (lipid, protein) of zoea 1 decapod crustacean
larvae
G.
Torres, L. Giménez, K. Anger-2002
Journal of Experimental Marine Biology and Ecology,
277(1): 43-60
Abstract:
Effects of reduced salinities on dry weight (DW) and
biochemical composition (total lipid and protein contents) of zoea 1 larvae
were evaluated in four decapod crustacean species differing in salinity
tolerance (Cancer pagurus, Homarus gammarus, Carcinus
maenas, Chasmagnathus granulata). The larvae were exposed to two
different reduced salinities (15ppt and 25ppt in C. granulata, 20ppt
and 25ppt in the other species) for a long (ca. 50% of the zoea 1 moulting
cycle) or a short period (16 h, starting at ca. 40% of the moulting cycle),
while a control group was continually maintained in seawater (32ppt).
In general, the increments in dry weight, lipid and
protein content were lower at the reduced salinities than in the control
groups. In the zoea 1 of H. gammarus (stenohaline) and C. pagurus
(most probably also stenohaline), the lipid and protein contents varied
greatly among treatments: larvae exposed to low salinities exhibited very
low lipid and protein contents at the end of the experiments compared to the
controls. In some cases, there were negative growth increments, i.e. the
larvae had, after the experimental exposure, lower lipid and protein
contents than at the beginning of the experiment. C. maenas
(moderately euryhaline) showed a lower variation in protein and lipid
content than the above species. The zoea 1 of C. granulata (fairly
euryhaline) showed the lowest variability in dry weight, protein and lipid
content. Since salinity tolerance (eury- v. stenohalinity) is associated
with the osmoregulatory capacity, our results suggest a relationship between
the capability for osmoregulation and the degree of change in the
biochemical composition of larvae exposed to variable salinities.
Besides larval growth of these species should be
affected by natural reductions of salinity occurring in coastal areas at
different time scales. These effects may be potentially important for
population dynamics since they should influence the number and quality of
larvae reaching metamorphosis.
(Biologische Anstalt Helgoland, Stiftung
Alfred-Wegener-Institut für Polar- und Meeresforschung, 27498 Helgoland,
Germany, Tel.: +49-4725-819348; fax: +49-4725-819369, gabi@fcien.edu.uy)