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Tom 11 Nr 4 (2012)

Artykuły

INDUCTION OF SOMATIC EMBRYOGENESIS IN Astrophytum asterias (Zucc.) Lem. IN THE ASPECT OF LIGHT CONDITIONS AND AUXIN 2,4-D CONCENTRATIONS

Przesłane: 29 grudnia 2020
Opublikowane: 2012-08-31

Abstrakt

Astrophytum asterias (Zucc.) Lem. is a cactus which is among those most desired by producers and collectors all across the world and, at the same time, a species
threatened with extinction in the natural environment. Micropropagation techniques can be helpful both in terms of its ex situ protection and its popularisation on the market, thus satisfying the needs of cacti breeders and collectors. Somatic embryogenesis is the most effective method of multiplication and it involves the formation of somatic embryos from vegetative cells. The medium, light conditions and type of explant demonstrate the key effect on its efficiency. Auxin 2,4-D (2,4-Dichlorophenoxyacetic acid) is most frequently applied to embryogenesis induction. In the present study we determined the effect of its concentration and light conditions on the efficiency of Astrophytum asterias somatic embryogenesis. Seeds were placed on the modified MS medium with a reduced content of
macronutrients and sucrose ½MS (pH 5.7 – before autoclaving). All the in vitro cultures were incubated in the growth room (24 ± 2°C, 16 h light/8 h dark photoperiod, the intensity of quantum irradiation: 24.3 μmol·m-2·s-1). After 14 days 70% of the seeds were produced of seedlings. To regenerate somatic embryos, halves of green seedlings were placed on the modified MS medium with auxin 2,4-D added at different concentrations: 5; 7 and 10 mg·dm-3, the MS0 medium without growth regulators was our control. To verify the effect of light conditions, half of explants were incubated in the light, and half in the dark. After 10 weeks of culture, the regenerated embryos were isolated, counted and measured. They were produced on all the media types, in both light conditions. The present research
confirmed a positive effect of 2,4-D and light on the number of explants forming embryoid structures and on the number of regenerating embryos. The most number of embryos per 1 explant (1.8) were obtained on the MS7 medium (7 mg·dm-3 2,4-D) in the light conditions.

Bibliografia

Aslam J., Mujib A., Nasim S. A., Sharma M., 2009. Screening of vincristine yield in ex vitro and in vitro somatic embryos derived plantlets of Catharanthus roseus L. (G). Don. Sci. Hort., 119, 325–329.
Fleischer Z., Schutz B., 1986. Kaktusy. PWRiL. Warszawa, 130–163.
Garro-Monge G., Gatica-Arias A. M., Valdez-Melara M., 2008. Somatic embryogenesis, plant regeneration and acemannan detection in aloe (Aloe barbadensis Mill.). Agronomia Costarricense, 32 (2), 41–52.
George E. F., Hall M. A., De Klerk G. J., 2008. Plant Propagation by Tissue Culture 3rd Edition, 335–355.
Giusti P., Vitti D., Fiocchetti F., Colla G., Saccardo F., Tucci M., 2002. In vitro propagation of three endangered cactus species. Sci. Hort., 95, 319–332.
Hoshino T., Cuello J.L., 2005. Environmental design considerations for somatic embryogenesis. Plant Cell Monographs, Springer-Verlag, Berlin Heidelberg, 2.
Infante R., 1992. In vitro axillary shoot proliferation and somatic embryogenesis of yellow pitaya Mediocactus coccineus (Salm-Dyck). Plant Cell Tiss. Org. Cult., 31 (2), 455–459.
Jasrai T.Y., Thaker K.N., D’Souza C.M., 2003. In vitro propagation of Euphorbia pulcherrima Willd. through somatic embryogenesis. Plant Cell Tiss. Org. Cult., 13 (1), 31–36.
Karimi N., Mofid M. R., Ebrahimi M., Naderi R., 2010. Effect of areole and culture medium on callus induction and regeneration Cereus peruvianus Mill. (Cactaceae). Trakia J. Sci., 8 (2), 31–35.
Lema-Rumińska J., 2011. Flow cytometric analysis of somatic embryos, shoots, and calli of the cactus Copiapoa tenuissima Ritt. forma monstruosa. Plant Cell Tiss. Org. Cult., 106, 531–535.
Lema-Rumińska J., Fijałkowska A., 2006. Dynamika wzrostu kalusa oraz regeneracja struktur embrioidalnych u kaktusa z rodzaju Gymnocalycium w zależności od warunków świetlnych. Zesz. Probl. Post. Nauk Roln., 510, 325–331.
Lema-Rumińska J., Licznerska I., 2004. Wpływ regulatorów wzrostu na regenerację kaktusa Copiapoa tenuissima Ritt. f. monstruosa z eksplantatów merystematycznych. Folia Univ. Agric. Stetin., 236 (94), 109–114.
Linhares F., Gomes F., Heredia F. F., Silva P. B., Faco O., Campos F., 2005. Somatic embryogenesis and plant regeneration in Opuntia ficus-indica (L.) Mill. (Cactaceae). Sci. Hort., 108, 15–21.
Marin-Hernandez T., Marquez-Guzman J., Rodriguez-Garay B., Rubluo A., 1998. Early stages in the development of somatic embryogenesis in Mammillaria san-angelensis Sanchez-Mejorada (Cactaceae). Phyton, 62 (1), 181–186.
Martinez-Avalos J. G., Golubov J., Mandujano M. C., Jurado E., 2007. Causes of individual mortality in the endangered star cactus Astrophytum asterias (Cactaceae); The effect of herbivores and disease in Mexican populations. J. Arid. Environm., 71, 250–258.
Martinez-Palacios A., Ortega-Larroccea M., Chavez V. M., 2003. Somatic embryogenesis and organogenesis of Agave victoriae-reginae: Considerations for its conservation. Plant Cell Tiss. Org. Cult., 74, 135–142.
McGranahan, G.H., Leslie C.A., Uratsu S.L., Dandekar A.M., 1990. Improved efficiency of walnut somatic embryo gene transfer system. Plant Cell Rep. 8, 512–516.
Moebius-Goldammer K., Mata-Rosas M., Chavez-Avila V., 2003. Organogenesis and somatic embryogenesis in Ariocarpus kotschoubeyanus (Lem.) K. Schum. (Cactaceae), an endemic Mexican species. In Vitro Cell Dev. Biol. Plant, 39, 388–393.
Murashige T., Skoog F., 1962. A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiol. Plant. 15, 473–497.
Pua E.C., Davey M.R. (eds.) 2010. Plant Developmental Biology – Biotechnological Perspectives, Springer-Verlag, Berlin Heidelberg, 2, 3–27.
Rubluo A., 1997. Micropropagation of Mammillaria species (Cactaceae). Biotechnol. Agr. Forest., 40, 193–205.
Sage D.O., Lynn J., Hammatt N., 2000. Somatic embryogenesis in Narcissus pseudonarcissus cv. Golden Harvest and St. Keverene. Plant Sci., 150, 209–216.
Santacruz-Ruvalcaba F., Gutierrez-Mora A., Rodriguez-Garay B., 1998. Somatic embryogenesis in some cactus and agave species. J. PACD, 3, 15–26.
Santarem E.R., Pelissier B., Finer J., 1997. Effect of ex plant orientation, pH, solidyfing agent and wounding on initiation of soybean somatic embryos. In Vitro Cell Dev. Biol. Plant, 33, 13–19.
Shi X., Dai X., Liu G., Bao M., 2009. Enhancement of somatic embryogenesis in camphor tree (Cinamonum camphora L.): osmotic stress and other factors affecting somatic embryo formation on hormone-free medium. Trees 23, 1033–1042.
Torres-Munoz L., Rodriguez-Garay B., 1996. Somatic embryogenesis in the threatened cactus Turbinicarpus pseudomacrochele (Buxbaum and Backeberg). J. PACD, 1, 36–38.
U.S. Fish and Wildlife Service, 2003. Recovery Plan for Star Cactus (Astrophytum asterias). Albuquerque, New Mexico, 1–10.

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