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Oxygen Supply and Limits on Aggregation of Embryos

Published online by Cambridge University Press:  11 May 2009

Richard R. Strathmann  and
Megumi F. Strathmann
Richard R. Strathmann
Affiliation:
Friday Harbor Laboratories Department of Zoology, University of Washington, 620 University Road, Friday Harbor, WA 98250, USA
Megumi F. Strathmann
Affiliation:
Friday Harbor Laboratories
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Extract

Effects of oxygen supply on development rates of embryos in gelatinous masses were tested with natural masses of three species of opisthobranch gastropods and artificial masses made with embryos of a sea urchin and agarose gel. When diffusive exchange was restricted for embryos in such masses, increased oxygen alone was sufficient to maintain development rates of embryos. Diffusive supply of oxygen is therefore a limiting factor for embryos clustered in gelatinous masses. Development rates were constant over a wide range of experimentally altered oxygen concentrations but retarded with oxygen below about 10% of air saturation. Some opisthobranch embryos exposed to low oxygen concentrations hatched with shorter shells. Delayed hatching and shorter shells at hatching were both associated with a central position in the globose gelatinous mass of one of the opisthobranch species, even in air-saturated and vigorously stirred water. The pH near the centres of the masses was lower when embryos were at more advanced stages; thus the intracapsular stirring caused by cilia of embryos at later stages does not compensate for their greater metabolic rates. The pH in some egg masses was about seven or lower, and this pH affected development in separate experiments. The masses approach limits for removal of wastes, although oxygen becomes limiting for rates of development before accumulation of wastes becomes limiting. Embryos of opisthobranchs that are normally aggregated and embryos of sea urchins that are normally dispersed were similarly tolerant of low oxygen concentrations and low pH. In respect to tolerance of hypoxia and accumulating wastes, embryos in many clades are preadapted for aggregation into masses, but there are limits on the size of the aggregation. Egg masses are commonly at those limits.

Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 75 , Issue 2 , May 1995 , pp. 413 - 428
Copyright
Copyright © Marine Biological Association of the United Kingdom 1995

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References

Amberson, W.R., 1928. The influence of oxygen tension upon the respiration of unicellular organisms. Biological Bulletin. Marine Biological Laboratory, Woods Hole, 55,7991.CrossRefGoogle Scholar
Burggren, W., 1985. Gas exchange, metabolism, and ‘ventilation’ in gelatinous frog egg masses. Physiological Zoology, 58, 503514.CrossRefGoogle Scholar
Chaffee, C. & Strathmann, R.R., 1984. Constraints on egg masses. I. Retarded development within thick egg masses. Journal of Experimental Marine Biology and Ecology, 84, 7383.CrossRefGoogle Scholar
Crisp, D.J., 1959. The rate of development of Balanus balanoides (L.) embryos in vitro. Journal of Animal Ecology, 28, 119132.CrossRefGoogle Scholar
Davenport, J., 1983. Oxygen and the developing eggs and larvae of the lumpfish, Cyclopterus lumpus. Journal of the Marine Biological Association of the Kingdom, 63, 633640.CrossRefGoogle Scholar
Giorgi, A.E. & Congleton, J.L., 1984. Effects of current velocity on development and survival of ling cod, Ophiodon elongata, embryos. Environmental Biology of Fishes, 10, 1527.Google Scholar
Hunter, T. & Vogel, S., 1986. Spinning embryos enhance diffusion through gelatinous egg masses. Journal of Experimental Marine Biology and Ecology, 96, 303308.CrossRefGoogle Scholar
Kress, A., 1975. Observations during embryonic development in the genus Doto (Gastropoda, Opisthobranchia). Journal of the Marine Biological Association of the United Kingdom, 55, 691701.CrossRefGoogle Scholar
Krogh, A., 1941. The Comparative Physiology of Respiratory Mechanisms. Philadelphia: University of Pennsylvania Press.CrossRefGoogle Scholar
Lutz, R.V., Marcus, N.H. & Chanton, J.P., 1992. Effects of low oxygen concentrations on the hatching and viability of eggs of marine calanoid copepods. Marine Biology, 114, 241247.CrossRefGoogle Scholar
Mann, R. & Rainer, J.S., 1990. Effect of decreasing oxygen tension on swimming rate of Crassostrea virginica (Gmelin, 1791) larvae. Journal of Shellfish Research, 9, 323327.Google Scholar
Pechenik, J.A., 1986. The encapsulation of eggs and embryos by molluscs: an overview. American Malacological Bulletin, 4, 165172.Google Scholar
Prosser, C.L., 1973. Comparative animal physiology, 3rd edition. Philadelphia: W.B. Saunders.Google Scholar
Seymour, R.S. & Roberts, J.D., 1991. Embryonic respiration and oxygen distribution in foamy and nonfoamy egg masses of the frog Limnodynastes tasmaniensis. Physiological Zoology, 64, 13221340.CrossRefGoogle Scholar
Strathmann, R.R. & Chaffee, C., 1984. Constraints on egg masses. II. Effect of spacing, size, and number of eggs on ventilation of masses of embryos in jelly, adherent groups, or thin-walled capsules. Journal of Experimental Marine Biology and Ecology, 84, 8593.CrossRefGoogle Scholar
Strathmann, R.R. & Strathmann, M.F., 1989. Evolutionary opportunities and constraints demonstrated by artificial gelatinous egg masses. In Reproduction, genetics and distributions of marine organisms (ed. J.S., Ryland and P.A., Tyler), pp. 201209. Fredensborg, Denmark: Olsen and Olsen.Google Scholar
Tang, P.-S. & Gerard, R.W., 1932. The oxygen tension - oxygen consumption curve of fertilized Arbacia eggs. Journal of Cellular and Comparative Physiology, 1, 503513.CrossRefGoogle Scholar
Wang, W.X. & Widdows, J., 1991. Physiological responses of mussel larvae Mytilus edulis to environmental hypoxia and anoxia. Marine Ecology Progress Series, 70, 223236.CrossRefGoogle Scholar