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Salinity effects on the growth, mortality and shell strength of Balanus amphitrite from the Salton Sea, California

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Abstract

The Salton Sea, the largest lake in California, has a salinity of around 43 g l-1 that is increasing by about 0.4 g l-1 y-1. A 15 month microcosm experiment was conducted to determined the effects of salinity (30, 39, 48, 57, and 65 g l-1) and tilapia ( Oreochromis mossambicus) on an assemblage of benthic and planktonic Salton Sea algae and invertebrates, including the barnacle Balanus amphitrite. Eleven months after the microcosms were established, acrylic plates containing newly settled B. amphitrite collected at the Salton Sea were placed in the microcosms to determine the effects of salinity on their growth and shell strength. The Brody-Bertalanffy growth model was fitted to the B. amphitrite growth data. Growth was fastest at 48 g l-1 and slowest at 65 g l-1. B. amphitrite grown at 39–48 g l-1 were the largest and required the greatest force to break, but the strength of the barnacle shell material declined steadily as the salinity increased. However, B. amphitrite at the higher salinities were shorter and had thicker walls relative to their diameters, which may have increased their structural stability. The effects of salinity on the mortality of adult B. amphitrite was determined in laboratory aquaria set up at 43, 60, 70, 75, 80, 90, and 100 g l-1. Salinities were achieved in two ways: by salt addition and by evaporation. Calculated 12-day LC50 values were 83 g l-1 when salinities were achieved through salt addition and 89 g l-1 when salinities were achieved through evaporation. Differences in B. amphitrite mortality between the two methods illustrate the importance of producing experimental salinity levels carefully. B. amphitrite is expected to become extinct within the Salton Sea when the salinity reaches 70–80 g l-1 and to show marked declines in abundance at salinities as low as 50 g l-1.

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References

  • Barnes, H., R. Read & J. A. Topinka, 1970. The behavior on impaction by solids of some common cirripedes and relation to their normal habitat. J. exp. mar. Biol. Ecol. 5: 70–87.

    Article  Google Scholar 

  • Carpelan, L. H., 1961. Zooplankton. In B. D. Walker (ed.), The ecology of the Salton Sea, in relation to the sportfishery. Cal. Fish Game Fish Bull. 113: 49–62.

  • Clare, A., R. K. Freet & M. McClary Jr., 1994. On the antennular secretion of the cyprid of Balanus amphitrite amphitrite settlement pheromone. J. mar. biol. Ass. U.K. 74: 243–250.

    Article  Google Scholar 

  • Costlow, J. D. & C. G. Bookhout, 1956. Molting and shell growth in Balanus amphitrite niveus. Biol. Bull. 110: 107–116.

    Google Scholar 

  • Fabens, A. J., 1965. Properties and fitting of the von Bertalanffy growth curve. Growth 29: 265–289.

    PubMed  CAS  Google Scholar 

  • Finney, D. J., 1971. Probit Analysis. Cambridge University Press, London, 333 pp.

    Google Scholar 

  • González, M. R., C. M. Hart, J. Verfaillie & S. H. Hurlbert, 1998a. Salinity and fish effects on Salton Sea microecosystems: water chemistry and nutrient cycling. Hydrobiologia 381: 105–128.

    Article  Google Scholar 

  • González, M. R., C. M. Hart, E. P. Simpson, R. Lara & S. H. Hurlbert, 1998b. Salinity and fish effects on Salton Sea microecosystems: Phytoplankton and periphyton. In prepn.

  • Hart, C. M., 1994. Salinity and fish effects on invertebrates of the Salton Sea: a microcosm experiment. MS Thesis, San Diego State University, San Diego, California, 102 pp.

    Google Scholar 

  • Hart, C. M., M. R. González, E. P. Simpson & S. H. Hurlbert, 1998. Salinity and fish effects on Salton Sea microecosystems: zooplankton and nekton. Hydrobiologia 381: 129–152.

    Article  Google Scholar 

  • Hirano, R. & J. Okushi, 1952. Studies on sedentary marine organisms I. Seasonal variations in the attachment and growth rates of barnacle cyprids in Aburatsubo Bay, near Misaki. Bull. Jpn. Soc. sci. Fish. 18: 639–643.

    Google Scholar 

  • Imperial Irrigation District, 1986. Environmental impact report for proposed water conservation program and initial water transfer. California State Clearinghouse #86012903.

  • Iwaki, T. & H. Hattori, 1987. First maturity and initial growth of some common species of barnacles in Japan. Bull. Fac. Fish., Mie Univ. 14: 11–19.

    Google Scholar 

  • Kuhl, D. L. & L. C. Oglesby, 1979. Reproduction and survival of the pileworm Nereis succinea in higher Salton Sea salinities. Biol. Bull. 157: 153–165.

    Google Scholar 

  • Linsley, R. H. & L. H. Carpelan, 1961. Invertebrate fauna. In B. D. Walker (ed.), The ecology of the Salton Sea, in relation to the sportfishery. Cal. Fish. Game Fish Bull. 113: 43–48.

  • Lowenstam, H. A. & S. Weiner, 1989. On Biomineralization. Oxford University Press, New York, 324 pp.

    Google Scholar 

  • Newman, W. A., 1967. On physiology and behavior of estuarine barnacles. Proc. mar. biol. Soc. India, Symp. Crust.: 1038–1066.

  • Ortega, S., 1981. Environmental stress, competition and dominance of Crassostrea virginica near Beaufort, North Carolina, USA. Mar. Biol. 62: 47–56.

    Article  Google Scholar 

  • Raimondi, P. T., 1992. Adult plasticity and rapid larval evolution in a recently isolated barnacle population. Biol. Bull. 182: 210–220.

    Google Scholar 

  • Reimer, A. A., 1976a. Description of a Tetraclita stalactifera panamensis community on a rocky intertidal shore of Panama. Mar. Biol. 35: 225–238.

    Article  Google Scholar 

  • Reimer, A. A., 1976b. Succession of invertebrates in vacant tests of Tetraclita stalactifera panamensis. Mar. Biol. 35: 239–251.

    Article  Google Scholar 

  • Simmons, E. G., 1957. An ecological survey of the Upper Laguna Madre. Pub. Inst. mar. Sci., Port Aransas, Texas 4: 156–200.

    Google Scholar 

  • Simpson, E. P., 1994. Salinity and fish effects on the Salton Sea benthos. MS Thesis. San Diego State University, San Diego, California, 116 pp.

    Google Scholar 

  • Simpson, E. P., M. R. Gonzélez, C. M. Hart & S. H. Hurlbert, 1998. Salinity and fish effects on Salton Sea microecosystems: benthos. Hydrobiologia 381: 153–177.

    Article  Google Scholar 

  • Vittor, B. A., 1968. The effects of oxygen tension, salinity, temperature and crowding on the distribution, growth, and survival of Balanus amphitrite Darwin in the Salton Sea, California. M.A. Thesis, San Diego State University, San Diego, California, 151 pp.

    Google Scholar 

  • Wainwright, S. A., W. D. Biggs, J. D. Currey & J. M. Gosline, 1976. Mechanical Design in Organisms. Princeton University Press, Princeton, 423 pp.

    Google Scholar 

  • Wolfram Research, Inc., 1993. Mathematica, Version 2.2. Wolfram Research, Inc., Champaign, III.

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  1. Department of Biology, San Diego State University, San Diego, CA, 92182, U.S.A

    E. Paul Simpson & Stuart H. Hurlbert

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  1. E. Paul Simpson
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  2. Stuart H. Hurlbert
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Simpson, E.P., Hurlbert, S.H. Salinity effects on the growth, mortality and shell strength of Balanus amphitrite from the Salton Sea, California. Hydrobiologia 381, 179–190 (1998). https://doi.org/10.1023/A:1003283709665

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