Synopsis
Elemental analyses, using wave-length dispersive electron microprobe techniques on otoliths from reared Atlantic herring larvae, Clupea harengus, showed trace quantities of strontium relative to that of calcium, and an inverse relationship between Sr/Ca concentration ratios and rearing temperature. These data are consistent with those for coral aragonite, in that there appears to be an inverse temperature effect on physiological incorporation of strontium in the otolith aragonite. Our determinations of Sr/Ca concentration ratios of lab-reared herring larvae showed that the deposition of strontium relative to calcium and the rearing temperature were related, where: T (° C) = −2.955 [Sr/Ca] × 1000 ± 19.172. This principle thus makes it possible to use Sr/Ca concentration ratios in fish otoliths to delineate past temperatures experienced by an individual. Further, combining electron microprobe analyses with scanning electron microscope (SEM) examinations of daily increments in the same otolith makes it possible to reconstruct the temperature history for an individual fish on a time scale of days. An example of the application of the technique to an approximately six-month-old field-caught herring larva is given, and the limitations of the technique are discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References cited
Amiel, A.J., G.M. Friedman & D.S. Miller. 1973. Distribution and nature of incorporation of trace elements in modern aragonitic corals. Sedimentology 20: 47–64.
Bagenal, T.B. (ed.) 1974. The ageing of fish. Proc. International Symposium on the Ageing of Fish, Univ. of Reading, Unwin Brothers, Ltd., Surrey. 234 pp.
Bennett, J.T., G.W. Boehlert & K.K. Turekian. 1982. Confirmation of longevity in Sebastes diploproa (Pisces: Scorpaenidae) from 210Pb/226Ra measurements in otoliths. Mar. Biol. 71: 209–215.
Brothers, E.B., C.P. Mathews & R. Lasker. 1976. Daily growth increments in otoliths from larval and adult fishes. U.S. Fish. Bull. 74: 1–8.
Calaprice, J.R. 1971. X-ray spectrometric and multivariate analysis of sockeye salmon (Onchorhynchus nerka) from different geographic regions. J. Fish. Res. Board Can. 38: 369–377.
Campana, S.E. 1984. Microstructural growth patterns in the otoliths of larval and juvenile starry flounder, Platichthys stellatus. Can. J. Zool. 62: 1507–1512.
Campana, S.E. & J.D. Neilson. 1985. Microstructure of fish otoliths. Can. J. Fish. Aquat. Sci. 42: 1014–1032.
Campana, S.E., J.A. Gagné & J. Munro. 1987. Otolith microstructure of larval herring (Clupea harengus): image or reality? Can. J. Fish. Aquat. Sci. 44: 1922–1929.
Carlstöm, D. 1963. A crystallographic study of vertebrate otoliths. Biol. Bull. (Woods Hole) 125: 441–463.
Casselman, J.M.1982. Chemical analyses of the optically different zones in eel otoliths. pp. 74–82. In: K.H. Loftus (ed.) Proceedings of the 1980 North American Eel Conference, Ontario Fisheries Tech. Rep. No. 4.
Chivas, A.R., P. De Deckker & J.M.G. Shelley. 1985. Strontium content of ostracods indicates lacustrine palaeosalinity. Nature 316: 251–253.
Dupré, B. & C.J. Allègre. 1983. Pb-Sr isotope variation in Indian Ocean basalts and mixing phenomena. Nature 303: 142–146.
Gauldie, R.W. & A. Nathan. 1977. Iron content of the otoliths of tarakihi (Teleostei: Cheilodactylidae). N.Z.J. Mar. Freshwater Res. 11: 179–191.
Gauldie, R.W., E.J. Graynoth & J. Illingworth. 1980. The relationship of the iron content of some fish otoliths to temperature. Comp. Biochem. Physiol. 66 (A): 19–24.
Gauldie, R.W., D.A. Fournier, D.E. Dunlop & G. Coote. 1986. Atomic emission and proton microprobe studies of the ion content of otoliths of chinook salmon aimed at recovering the temperature life history of individuals. Comp. Biochem. Physiol. 84 (A): 607–615.
Geffen, A.J. 1982. Otolith ring deposition in relation to growth rate in herring (Clupea harengus) and turbot (Scophthalmus maximus) larvae. Mar. Biol. 71: 317–326.
Graham, D.W., M.L. Bender, D.F. Williams & L.D. Keigwin, Jr. 1982. Strontium-calcium ratios in Cenozoic planktonic foraminifera. Geochim. Cosmochim. Acta. 46: 1281–1292.
Gunatilaka, A. 1981. Biogeochemistry of strontium. pp. 19–46. In: S.C. Skoryna (ed.) Handbook of Stable Strontium, Plenum Press, New York.
Hallam, A. & N.B. Price. 1968. Environmental and biochemical control of strontium in shells of Cardium edule. Geochim. Cosmochim. Acta 32: 319–328.
Kinsman, D.J.J. 1969. Interpretation of Sr2+ concentrations in carbonate minerals and rocks. J. Sediment. Petrol. 39: 486–508.
Kinsman, D.J.J. & H.D. Holland. 1969. The co-precipitation of cations of CaC03. IV. The co-precipitation of Sr2+ with aragonite between 16° and 96° C. Geochim. Cosmochim. Acta 33: 1–17.
Lough, R.G., M. Pennington, G.R. Bolz & A.A. Rosenberg. 1982. Age and growth of larval Atlantic herring, Clupea harengus L., in the Gulf of Maine-Georges Bank region based on otolith growth increments. U.S. Fish. Bull. 80: 187–199.
Lowenstam, H.A. 1963. Sr/Ca ratio of skeletal aragonites from recent marine biota at Palau and from fossil gastropods. pp. 114–132. In: H. Craig, S.L. Miller & G.J. Wasserburg (ed.) Isotopic and Cosmic Chemistry, North Holland Publ. Co., Amsterdam.
McGurk, M.D. 1987. Age and growth of Pacific herring larvae based on length-frequency analysis and otolith ring number. Env. Biol. Fish. 20: 33–47.
Morton, J.P. & L.E. Long. 1984. Rb-Sr ages of glauconite recrystallization: Dating times of regional emergence above sea level. J. Sediment. Petrol. 54: 495–506.
Mugiya, Y., N. Watabe, J. Yamada, J.M. Dean, D.G. Dunkelberger & M. Shimizu. 1981. Diurnal rhythm in otolith formation in the goldfish Carassius auratus. Comp. Biochem. Physiol. 68A: 659–662.
Pagett, R.M. 1985. Some observations upon the distribution of strontium in four species of ophiuroids-Ophiocomina nigra (Abildgaard), Ophiura albida (Forbes), Ophiothrix suensoni (Lütken) and Ophioderma cinereum (Müller and Troschel). J. mar. biol. Ass. U.K. 65: 293–303.
Palmer, M.R. & H. Elderfield. 1985. Sr isotope composition of seawater over the past 75 Myr. Nature 314: 526–528.
Pannella, G. 1971. Fish otoliths: daily growth layers and periodical patterns. Science 173: 1124–1127.
Papadopoulou, C., G.D. Kanias & E. Moraitopoulou-Kassimati. 1980. Trace element content in fish otoliths in relation to age and size. Mar. Pollut. Bull. 11: 68–72.
Radtke, R.L. 1984. Cod fish otoliths: Information storage structures. Flødevigen rapportser. 1: 273–298.
Radtke, R.L. 1989. Strontium-calcium concentration ratios in fish otoliths as environmental indicators. Comp. Biochem. Physiol. 92 (A): 189–193.
Radtke, R.L. & J.M. Dean. 1982. Increment formation in the otoliths of embryos, larvae, and juveniles of the mummichog Fundulus heteroclitus. U.S. Fish. Bull. 80: 201–215.
Radtke, R.L. & T.E. Targett. 1984. Rhythmic structural and chemical rhythmic patterns in the otoliths of the Antarctic fish Notothenia larseni: their application to the age determination. Polar Biology 3: 203–210.
Radtke, R.L., R.A. Kinzie, III & S.D. Folsom. 1988. Age at recruitment of Hawaiian freshwater gobies. Env. Biol. Fish. 23: 205–213.
Ralston, S. 1976. Age determination of a tropical reef butterflyfish utilizing daily growth rings of otoliths. U.S. Fish. Bull. 74: 990–994.
Schneider, R.C. & S.V. Smith. 1982. Skeletal Sr content and density in Porites spp. in relation to environmental factors. Mar. Biol. 66: 121–131.
Six, L.D. & H.F. Horton. 1977. Analysis of age determination methods for yellowtail rockfish, canary rockfish, and black rockfish off Oregon. U.S. Fish. Bull. 75: 405–414.
Smith, S.V., R.W. Buddemeier, R.C. Redalje & J.E. Houck. 1979. Strontium-calcium thermometry in coral skeletons. Science 204: 404–407.
Struhsaker, P. & J.H. Uchiyama. 1976. Age and growth of nehu, Stolephorus purpureus (Pisces: Engraulidae), from the Hawaiian Islands as indicated by daily growth increments of sagittae. U.S. Fish. Bull. 74: 9–17.
Tanaka, K., Y. Mugiya & J. Yamada. 1981. Effects of photoperiod and feeding on daily growth patterns in otoliths of juvenile Tilapia nilotica. U.S. Fish. Bull. 79: 459–466.
Taubert, B.D. & D.W. Coble. 1977. Daily rings in otoliths of three species of Lepomis and Tilapia mossambica. J. Fish. Res. Board Can. 34: 332–340.
Townsend, D.W. 1980. Microstructural growth increments in some Antarctic fish otoliths. Cybium 8: 17–22.
Townsend, D.W., R.L. Radtke, M.A. Morrison & S.D. Folsom. 1989. Recruitment implications of larval herring over-wintering distributions in the Gulf of Maine, inferred using a new otolith technique. ]Mar. Ecol. Prog. Ser. (in press).
Weber, J.N. 1973. Incorporation of strontium into reef coral skeletal carbonate. Geochim. Cosmochim. Acta. 37: 2173–2190.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Radtke, R.L., Townsend, D.W., Folsom, S.D. et al. Strontium:cakium concentration ratios in otoliths of herring larvae as indicators of environmental histories. Environ Biol Fish 27, 51–61 (1990). https://doi.org/10.1007/BF00004904
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00004904