Abstract
I examine how the population biology of pelagic copepods depends on their mating biology using field data and a simple demographic model. Among calanoid copepods, two distinct patterns emerge. Firstly, copepods that lack seminal receptacle and require repeated mating to stay fertilized have near equal adult sex ratios in field populations. Winter population densities are orders of magnitude less than the critical population density required for population persistence, but populations survive winter seasons as resting eggs in the sediment. Population growth in these species is potentially high because they have on average a factor of 2 higher egg production rates than other pelagic copepods. Secondly, other copepods require only one mating to stay fertile, and populations of these species have strongly female-skewed adult sex-ratios in field populations. Resting eggs have not been described within this group. Winter population sizes are well predicted by the critical density required for population persistence which, in turn, is closely related to the body-size-dependent mate-search capacity. Thus, the different requirements for mating lead in the first case to a more opportunistic reproductive strategy that implies rapid colonization of the pelagic during productive seasons, and in the second case to a strategy that allows maintenance of a pelagic populations during unproductive seasons. Positive density dependent population growth during periods of low population density (‘Allee effect’) amplifies population density variation during winter into the subsequent summer, thus explaining why summer densities appear to depend more on winter densities than on current growth opportunities in pelagic copepods.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ambler JW, Broadwater SA, Buskey EJ, Peterson JO (1996) Mating behaviour in swarms of Dioithona oculata. In: Lenz PH, Hartline DK, Purcell JE, MacMillan DL (eds) Zooplankton: sensory ecology and physiology. Gordon and Breach, Basel, pp 287–299
Bagøien E, Kiørboe T (2005) Blind dating—mate finding in planktonic copepods. III. Hydromechanica communication in Acartia tonsa. Mar Ecol Prog Ser (in press)
Berger I, Maier G (2001) The mating and reproductive biology of the freshwater planktonic calanoid copepod Eudiaptomus gracilis. Freshw Biol 46:787–794
Blades PI (1977) Mating behavior of Centropages typicus (Copepoda: Calanoida). Mar Biol 40:57–64
Buskey EJ (1998) Components of mating behaviour in planktonic copepods. J Mar Syst 15:13–21
Charnov EL (1982) The theory of sex allocation. Princeton University Press, Princeton, p 355
Colebrook JM (1985) Continuous plankton records: overwintering and annual fluctuations in the abundance of zooplankton. Mar Biol 84:261–265
Conover RJ (1956) Oceanography of Long Island Sound, 1952–1954. VI. Biology of Acartia clausi and A. tonsa. Bull Bingham Oceanogr Coll 15:156–233
Digby PSB (1951) The biology of the small planktonic copepods of Plymouth. J Mar Biol Assoc UK 29:393–438
Durbin EG, Garrahan PT, Casas MC (2000) Abundance and distribution of Calanus finmarchicus in the Georges Bank during 1995 and 1996. ICES J Mar Sci 57:1664–1685
Fisher RA (1930) The genetical theory of natural selection. Oxford University Press, London
Flemminger A (1985) Dimorphism and sex change in copepods of the family Calanidae. Mar Biol 88:273–294
Gascoigne J, Lipicus RN (2004) Allee effects in marine systems. Mar Ecol Prog Ser 269:49–59
Gauld DT (1957) Copulation in calanoid copepods. Nature 180:510
Gerritsen J (1980) Sex and parthenogenesis in sparse populations. Am Nat 115:718–742
Goswami SC (1978) Developmental stages, growth and sex ratio in Pseudodiaptomus binghami Sewell (Copepoda: Calanoida). Indian J Mar Sci 7:103–109
Hayward TL (1981) Mating and the depth distribution of an oceanic copepod. Limnol Oceanogr 26:374–377
Hirst AG, Kiørboe T (2002) Mortality of marine planktonic copepods: global rates and patterns. Mar Ecol Prog Ser 230:195–209
Hopkins CCE (1982) The breeding biology of Euchaete norvegica (Boeck) (Copepoda, Calanoida) in Loch Etive, Scotland—assessment of breeding intensity in terms of seasonal cycles in the sex-ratio, spermatophore attachment, and egg-sac production. J Exp Mar Biol Ecol 60:91–102
Huntley ME, Lopez MDG (1992) Temperature-dependent production of marine copepods—a global synthesis. Am Nat 140:201–242
Ianora A, Dicarlo BS, Mascellaro P (1989) Reproductive biology of the planktonic copepod Temora stylifera. Mar Biol 101:187–197
Ianora A, Miralto A, Buttino I, Romano G, Poulet SA (1999) First evidence of some dinoflagellates reducing male copepod fertilization capacity. Limnol Oceanogr 44:147–153
Irigoien X, Obermüller B, Head RN, Harris RP et al (2000) The effect of food on the determination of sex ratio in Calanus spp: evidence from experimental studies and field data. ICES J Mar Sci 57:1752–1763
Katona SK (1975) Copulation in the copepod Eurytemora affinis (Poppe, 1880). Crustaceana 28:89–95
Kiørboe T, Bagøien E (2005) Motility patterns and mate encounter rates in planktonic copepods. Limnol Oceanogr 50:1999–2007
Kiørboe T, Nielsen TG (1994) Regulation of zooplankton biomass and production in a temperate, coastal ecosystem. I. Copepods. Limnol Oceanogr 39:493–507
Kiørboe T, Sabatini M (1994) Reproductive and life cycle strategies in egg-carrying cyclopoid and free-spawning calanoid copepods. J Plankton Res 16:1353–1366
Kiørboe T, Sabatini M (1995) The scaling of fecundity, growth and development in planktonic copepods. Mar Ecol Prog Ser 120:285–298
Kiørboe T, Bagøien E, Thygesen UH (2005) Blind dating—mate finding in planktonic copepods. II. The pheromone cloud of Pseudocalanus elongatus. Mar Ecol Prog Ser 300:117–128
Kouwenberg JHM (1993) Sex ratio of calanoid copepods in relation to population composition in the northwestern Mediterranean. Crustaceana 64:281–299
Lazzaretto FF, Battaglia B (1994) Reproductive behaviour in the harpacticoid copepod Tigriopus fulvus. Hydrobiologia 292/293:229–234
Lee WY, McAlice BJ (1979) Seasonal succession and breeding cycles of three species of Acartia (Copepoda: Calanoida) in a Maine estuary. Estuaries 2:228–235
Liang D, Uye S (1996a) Population dynamics and production of the planktonic copepods in a eutrophic inlet of the Inland Sea of Japan. III. Acartia omori. Mar Biol 125:109–117
Liang D, Uye S (1996b) Population dynamics and production of the planktonic copepods in a eutrophic inlet of the Inland Sea of Japan. III. Paracalanus sp. Mar Biol 127:219–227
Liang D, Uye S (1997) Seasonal reproductive biology of the egg-carrying calanoid copepod Pseudodiaptomus marinus in a eutrophic inlet of the Inland Sea of Japan. Mar Biol 128:409–414
Maly EJ, Maly MP (1999) Body size and sexual size dimorphism in calanoid copepods. Hydrobiologia 391:173–179
Marshall SM (1949) On the biology of the small copepods in Loch Striven. J Mar Biol Assoc UK 28:45–122
Marshall SM, Orr AP (1952) On the biology of Calanus finmarchicus. VII. Factors affecting egg production. J Mar Biol Assoc UK 30:527–547
Marshall SM, Nicholls AG, Orr AP (1934) On the biology of Calanus finmarchicus. V. Seasonal distribution, size, weight and chemical composition in Loch Striven in 1933, and their relation to the phytoplankton. J Mar Biol Assoc UK 19:793–827
Mauchline J (1998) The biology of calanoid copepods. Adv Mar Biol 33:1–710
Miller CB, Crain JA, Marcus NH (2005) Seasonal variation of male-type antennular setation in female Calanus finmarchicus. Mar Ecol Prog Ser 301:217–229
Moraïtou-Apostolopoulou M (1972) Sex ratio in the pelagic copepods Temora stylifera Dana and Centropages typicus Krøyer. J Exp Mar Biol Ecol 8:83–87
Ohtsuka S, Huys R (2001) Sexual dimorphism in calanoid copepods: morphology and function. Hydrobiologia 453/454:441–466
Parrish KK, Wilson DF (1978) Fecundity studies on Acartia tonsa (Copepoda: Calanoida) in standardized culture. Mar Biol 46:65–81
Schnack SB (1978) Seasonal change of zooplankton in Kiel Bay. III. Calanoid copepods. Kiel Meeresforsch 4:201–209
Smetacek V, Pollehne F (1986) Nutrient cycling in pelagic systems: a reappraisal of the conceptual framework. Ophelia 26:401–428
Smith SL, Lane PVZ (1985) Laboratory studies of the marine copepod Centropages typicus: egg production and development rates. Mar Biol 85:153–162
Stephens PA, Sutherland WJ, Freckleton RP (1999) What is the Allee effect. Oikos 87:185–190
Svensen C, Tande K (1999) Sex change and female dimorphism in Calanus finmarchicus. Mar Ecol Prog Ser 176:93–102
Tsuda A, Miller CB (1998) Mate-finding behaviour in Calanus marshallae frost. Phil Trans R Soc Lond B 353:713–720
Williamson CE, Butler NM (1987) Temperature, food and mate limitation of copepod reproductive rates: separating the effects of multiple hypotheses. J Plankton Res 9:821–836
Acknowledgements
The study was supported by a grant from the Danish National Science Research Council (21-01-0549). Kajsa Tönneson and Peter Munk gave permission to use their unpublished data, and Sigrid Schnack-Schiel supplied the original data from Schnack (1978). Ellen Toby, George Jackson and Andy Visser helped solve equations. Christian Jørgensen and Øyvind Fiksen provided essential comments to the manuscript. I thank them all.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by Ulrich Sommer
Rights and permissions
About this article
Cite this article
Kiørboe, T. Sex, sex-ratios, and the dynamics of pelagic copepod populations. Oecologia 148, 40–50 (2006). https://doi.org/10.1007/s00442-005-0346-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00442-005-0346-3