Highly profitable black caviar market and the depletion of wild sturgeon stocks warrant improvements in sturgeon aquaculture. Therefore, chromosomal manipulations, particularly gynogenesis, are focused on for increasing the ratio of females over males in progeny. The present study focused on optimizing chromosomal manipulations in sturgeons, particularly gynogenesis. The reasons of low survival rates were analyzed and the critical steps of gynogenesis induction processes were optimized. In addition, alternative ways of DNA inactivation in sperms were investigated, as well as the influence of native light-dependent DNA repair mechanisms on gynogenesis induction. Methods of interspecific gynogenesis usage for simplifying gynogenetic progeny separation were also proposed. Spectrophotometry analysis was used to investigate the ability of UV light, as the most common DNA inactivating agent, to penetrate into sperm. In addition, investigation of UV-irradiated sperm motility and results of partial gynogenesis induction showed that low transparency of sperms for UV-light can cause significant heterogeneity of UV-irradiation. As a result, a proper dilution of sperm was suggested as a critical step for homogeneous UV-irradiation of samples. Gynogenesis in sterlet was induced with chemical agents that damage sperm DNA, as an alternative to UV irradiation for applied in large-scale production of gynogenotes. All tested substances showed ability to inactivate DNA in spermatozoa, and thus producing gynogenotes. Negative impact of treatments with chemical agents on the sperm motility was observed. Subsequently, these treatments had a low efficiency of gynogenesis induction. The highest percentage of produced gynogenetic larvae 19.8 ? 8.9% was obtained by treatment with aminomethyl-4,5?,8-trimethylpsoralen (AMT) at 50 ?M followed by UV-A (360 nm) irradiation at dose of 900 J/m2. Therefore, this treatment could be used as a substitute for commonly used UV-C irradiation, e.g., in the case of large volumes of sperm. Detailed investigation of photoreactivation in sturgeon sperm revealed a significant level of light-dependent DNA restoration in sperms irradiated with high doses of UV-C light. Induction of gynogenesis with UV-C irradiation followed by exposure to visible light resulted in significant deviations from the typical Hertwig effect. In contrast, the red light with a wavelength of more than 600 nm did not result in decreased DNA damage, instead a moderate increase in damage was observed, i.e., it did not induce photoreactivation. Therefore, the use of infrared light to illuminate work stations during the induction of gynogenesis is suggested. The use of interspecific gynogenesis, particularly gametes of sturgeon species with different ploidy levels, was suggested as a way to simplify the separation of gynogenotes. In addition, application of this method allowed studying the effectiveness of DNA-inactivation and ploidy restoration treatments separately, as well as evaluation of fitness parameters and survival rates in each group of progeny without the physical separation of fish. Finally, the protocol for tetraploidization in sterlet was optimized for the prospective using tetraploid individuals for the induction of gynogenesis and androgenesis with diploid eggs and sperm. In conclusion, the described methods and protocols allowed gynogenesis induction in sturgeons with a survival rate sufficient for aquaculture, taking into consideration their high fertility, although further studies of the consequences of this treatment on fish is required.
Identifer | oai:union.ndltd.org:nusl.cz/oai:invenio.nusl.cz:175341 |
Date | January 2014 |
Creators | LEBEDA, Ievgen |
Source Sets | Czech ETDs |
Language | English |
Detected Language | English |
Type | info:eu-repo/semantics/doctoralThesis |
Rights | info:eu-repo/semantics/restrictedAccess |
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