Angell R.W., Hancock, J.W. (1989). Response of eggs of Heterocypris incongruens (Ostracoda) to experimental stress. J. Crustacean Bio. 9: 381-86.
Castellani C., Lucas, I.A.N. (2003). Seasonal variation in egg morphology and hatching success in the calanoid copepods Temora longicorhis, Acartia clausi and Centropages hamatus. J. Plankton Res. 5: 527–37.
Dumont H.J., Nandini S. and Sarma S.S.S. (2002) Cyst ornamentation in aquatic invertebrates: a defense against egg- predation. Hydrobiologia. 486: 161–67.
Fanid L.M., Seidgar M. and Takami G.A. (2007) A comparative SEM morphological study on the egg shell in some Anostracans (Crustacea: Branchiopoda) from east Azerbaijan province of Iran. Iranian J. Fisheries Sci. 7:101–10.
Gilchrist B.M. (1978) Scanning electron microscope studies of the egg shell in some Anostraca (Crustacea: Branchiopoda). Cell Tissue Res. 193: 337–51.
Horne D.J. and Martens K. (1998) An assessment of the importance of resting eggs for the evolutionary success of Mesozoic non-marine Cypridoidean Ostracoda (Crustacea). Arch. Hydrobiol, Special Issues Advanced Limnology 52; 549–61.
Kesling R.V. (1951) The morphology of ostracod molt stages. Illinois Biological Monographs, University of Illinois Press, Chicago. pp. 324
Kornicker L.S. and Sohn I.G. (1971) Viability of ostracod eggs egested by sh and effect of digestive uids on ostracode shells – ecologic and paleoecologic implications. Bull. Center Rech. Pau – SNPA. 5: 125 – 35.
Matzke-Karasz R. (2005) Giant spermatozoon coiled in small egg: Fertilization mechanisms and their implications for evolutionary studies on Ostracoda (Crustacea). J. Exp. Zool. (Mol. Dev. Evol.) 304: 129–49.
Mc Kenzie K.G. and Hussainy S.U. (1968) Relevance of a freshwater Cytherid (Crustacea, Ostracoda) to the continental drift hypothesis. Nature 220: 806-808.
McLay C.L. (1978) The population biology of Cyprinotus carolinensis and Herpetocypris reptans (Crustacea, Ostracoda). Can. J. Zoolog. 56: 1170-79
Mura G. (2001) Morphological diversity of the resting eggs in the Anostracan genus Chirocephalus (Crustacea, Branchiopoda). Hydrobiologia 450: 173– 85.
Özuluğ O. and Suludere Z. (2012) Morphology of dry- resistant eggs in parthenogenetik Heterocypris incongruens (Ramdohr, 1808) (Ostracoda, Crustacea). Acta. Biol. Hung. 63: 333–41.
Radzikowski J. (2013) Resistance of dormant stages of planktonic invertebrates to adverse environmental conditions. J. Plankton Res. 35: 707-23.
Rossi V., Gandol A. and Menozzi P. (1996) Egg diapause and clonal structure in parthenogenetic populations of Heterocypris incongruens (Ostracoda). Hydrobiologia. 320: 45-54.
Rossi V., Benassi G., Belleti F. and Menozzi P. (2011) Colonization, population dynamics, predatory behaviour and cannibalism in Heterocypris incongruens (Crustacea: Ostracoda). J. limnol. 70: 102-8.
Smith R.J. (1999) Possible fossil ostracod (Crustacea) eggs from the Cretaceous of Brazil. J Micropalaeontol. 18: 81-7.
Sohn I.G. and Kornicker L.S. (1979) Viability of freeze-dried eggs of the Heterocypris incongruens. Taxonomy, biostratigraphy and distribution of Ostracodes (proceedings of the VII international symposium on ostracodes), 1–3.
Spencer M. and Blaustein L. (2001) Risk of predation and hatching of resting eggs in the ostracoda Heterocypris incongruens. J. Crustacean Biol. 21: 575-81
Vandekerkhove J. Martens K., Rossetti G., Mesquita-Joanes F. and Namiotko, T. (2013) Extreme tolerance to environmental stress of sexual and parthenogenetic resting eggs of Eucypris virens (Crustacea- Ostracoda). Freshwater Biol. 58: 237-47.
Subitaneous egg type and focus on ancestral ruins possibility in Cypris pubera O.F. Müller, 1776 (Ostracoda, Crustacea)
The most important evolutional gain of some non-marine ostracods are dry- resistant eggs. The “pause-
wait” is carried out until suitable conditions are developed during the evolution of dry-resistant eggs.
Through the egg-resting period, survival of ostracod individuals depends on a temporary water body. In
this paper, we investigated Cypris pubera O.F. Müller, 1776, eggs via Scanning Electron Microscope
(SEM). We observed two different types of eggs in the life cycle of one specimen. The subitaneous egg
type of the C. pubera is shown first time here. Subitaneous egg can be only seen in first laying period
which explains its role in the growth stage during the C. pubera life cycle.
Angell R.W., Hancock, J.W. (1989). Response of eggs of Heterocypris incongruens (Ostracoda) to experimental stress. J. Crustacean Bio. 9: 381-86.
Castellani C., Lucas, I.A.N. (2003). Seasonal variation in egg morphology and hatching success in the calanoid copepods Temora longicorhis, Acartia clausi and Centropages hamatus. J. Plankton Res. 5: 527–37.
Dumont H.J., Nandini S. and Sarma S.S.S. (2002) Cyst ornamentation in aquatic invertebrates: a defense against egg- predation. Hydrobiologia. 486: 161–67.
Fanid L.M., Seidgar M. and Takami G.A. (2007) A comparative SEM morphological study on the egg shell in some Anostracans (Crustacea: Branchiopoda) from east Azerbaijan province of Iran. Iranian J. Fisheries Sci. 7:101–10.
Gilchrist B.M. (1978) Scanning electron microscope studies of the egg shell in some Anostraca (Crustacea: Branchiopoda). Cell Tissue Res. 193: 337–51.
Horne D.J. and Martens K. (1998) An assessment of the importance of resting eggs for the evolutionary success of Mesozoic non-marine Cypridoidean Ostracoda (Crustacea). Arch. Hydrobiol, Special Issues Advanced Limnology 52; 549–61.
Kesling R.V. (1951) The morphology of ostracod molt stages. Illinois Biological Monographs, University of Illinois Press, Chicago. pp. 324
Kornicker L.S. and Sohn I.G. (1971) Viability of ostracod eggs egested by sh and effect of digestive uids on ostracode shells – ecologic and paleoecologic implications. Bull. Center Rech. Pau – SNPA. 5: 125 – 35.
Matzke-Karasz R. (2005) Giant spermatozoon coiled in small egg: Fertilization mechanisms and their implications for evolutionary studies on Ostracoda (Crustacea). J. Exp. Zool. (Mol. Dev. Evol.) 304: 129–49.
Mc Kenzie K.G. and Hussainy S.U. (1968) Relevance of a freshwater Cytherid (Crustacea, Ostracoda) to the continental drift hypothesis. Nature 220: 806-808.
McLay C.L. (1978) The population biology of Cyprinotus carolinensis and Herpetocypris reptans (Crustacea, Ostracoda). Can. J. Zoolog. 56: 1170-79
Mura G. (2001) Morphological diversity of the resting eggs in the Anostracan genus Chirocephalus (Crustacea, Branchiopoda). Hydrobiologia 450: 173– 85.
Özuluğ O. and Suludere Z. (2012) Morphology of dry- resistant eggs in parthenogenetik Heterocypris incongruens (Ramdohr, 1808) (Ostracoda, Crustacea). Acta. Biol. Hung. 63: 333–41.
Radzikowski J. (2013) Resistance of dormant stages of planktonic invertebrates to adverse environmental conditions. J. Plankton Res. 35: 707-23.
Rossi V., Gandol A. and Menozzi P. (1996) Egg diapause and clonal structure in parthenogenetic populations of Heterocypris incongruens (Ostracoda). Hydrobiologia. 320: 45-54.
Rossi V., Benassi G., Belleti F. and Menozzi P. (2011) Colonization, population dynamics, predatory behaviour and cannibalism in Heterocypris incongruens (Crustacea: Ostracoda). J. limnol. 70: 102-8.
Smith R.J. (1999) Possible fossil ostracod (Crustacea) eggs from the Cretaceous of Brazil. J Micropalaeontol. 18: 81-7.
Sohn I.G. and Kornicker L.S. (1979) Viability of freeze-dried eggs of the Heterocypris incongruens. Taxonomy, biostratigraphy and distribution of Ostracodes (proceedings of the VII international symposium on ostracodes), 1–3.
Spencer M. and Blaustein L. (2001) Risk of predation and hatching of resting eggs in the ostracoda Heterocypris incongruens. J. Crustacean Biol. 21: 575-81
Vandekerkhove J. Martens K., Rossetti G., Mesquita-Joanes F. and Namiotko, T. (2013) Extreme tolerance to environmental stress of sexual and parthenogenetic resting eggs of Eucypris virens (Crustacea- Ostracoda). Freshwater Biol. 58: 237-47.
Özuluğ O, Suludere Z. Subitaneous egg type and focus on ancestral ruins possibility in Cypris pubera O.F. Müller, 1776 (Ostracoda, Crustacea). Eur J Biol. August 2017;75(2):1-6.