| one publication added to basket [77186] | First year growth in the lithodids Lithodes santolla and Paralomis granulosa reared at different temperatures
Calcagno, J.A.; Lovrich, G.A.; Thatjse, S.; Nettelmann, U.; Anger, K. (2005). First year growth in the lithodids Lithodes santolla and Paralomis granulosa reared at different temperatures. J. Sea Res. 54(3): 221-230. https://dx.doi.org/10.1016/j.seares.2005.04.004
In: Journal of Sea Research. Elsevier/Netherlands Institute for Sea Research: Amsterdam; Den Burg. ISSN 1385-1101; e-ISSN 1873-1414, more
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| Keywords |
Cultures > Shellfish culture > Crustacean culture
Developmental stages > Larvae
Environmental effects > Temperature effects
Growth rate
Properties > Biological properties > Tolerance > Temperature tolerance
Rearing
Lithodes santolla (Molina, 1782) [WoRMS]; Paralomis granulosa (Hombron & Jacquinot, 1846) [WoRMS]
PSW, Argentina [Marine Regions]; PSW, Chile [Marine Regions]; PSW, South America [Marine Regions]
Marine/Coastal |
| Author keywords |
lithodidae; Lithodes santolla; Paralomis granulosa; temperaturetolerance; juvenile development; king crabs; stone crabs |
| Authors | | Top |
- Calcagno, J.A.
- Lovrich, G.A.
- Thatjse, S.
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| Abstract |
The southern king crab, Lithodes santolla Molina, and stone crab, Paralomis granulose Jacquinot, inhabit the cold-temperate waters of southernmost South America (southern Chile and Argentina), where stocks of both species are endangered by overfishing. Recent investigations have shown that these crabs show life-cycle adaptations to scarcity of food and low temperatures prevailing in subantarctic regions, including complete lecithotrophy of all larval stages and prolonged periods of brooding and longevity. However, growth and development to maturity are slow under conditions of low temperatures, which may explain the particular vulnerability of subpolar lithodids to fisheries. In the present study, juvenile L. santolla and P. granulose were individually reared in the laboratory at constant temperatures ranging from 3-15 °C, and rates of survival and development through successive instars were monitored throughout a period of about nine months from hatching. When the experiments were terminated, L. santolla had maximally reached juvenile instar IV (at 6 °C), V (9 °C), or VII (15 °C). In P. granulose the maximum crab instar reached was II (at 3 °C), V (6 °C), V (9 °C), or VII (15 °C). The intermoult period decreased with increasing temperature, while it increased in successively later instars. In consequence, growth rate showed highly significant differences among temperatures (P<0.001). Growth-at-moult was highest at 9 °C. Rates of survival decreased significantly in juvenile P. granulose with increasing temperature. Only at 15 °C in L. santolla, was a significantly enhanced mortality found compared with lower temperatures. Our results indicate that juvenile stages of L. santolla and P. granulose are well adapted to 5-10°C, the range of temperatures typically prevailing in subantarctic marine environments. In spite of causing higher mortality rates, higher rearing temperatures (12-15 °C) should accelerate the rates of growth and maturation, which may be favourable for projects aiming at aquaculture or repopulation of overexploited king crab stocks. |
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