Direct and Indirect Somatic Embryogenesis from Petiole and Leaf Explants of Purple Fan Flower (Scaevola aemula R. Br. cv. 'Purple Fanfare')
Direct and indirect somatic embryogenesis (SE) from
petiole and leaf explants of Scaevola aemula R. Br. cv. 'Purple
Fanfare' was achieved. High frequency of somatic embryos was
obtained directly from petiole and leaf explants using an inductive
plant growth regulator signal thidiazuron (TDZ). Petiole explants
were more responsive to SE than leaves. Plants derived from somatic
embryos of petiole explants germinated more readily into plants. SE
occurred more efficiently in half-strength Murashige and Skoog
(MS) medium than in full-strength MS medium. Non-embryogenic
callus induced by 2, 4-dichlorophenoxyacetic acid was used to
investigate the feasibility of obtaining SE with TDZ as a secondary
inductive plant growth regulator (PGR) signal. Non-embryogenic
callus of S. aemula was able to convert into an “embryogenic
competent mode" with PGR signal. Protocol developed for induction
of direct and indirect somatic embryogenesis in S. aemula can
improve the large scale propagation system of the plant in future.
[1] T. Senaratna, B. D. McKersie and S. R. Bowley, "Artificial seeds:
Induction of desiccation tolerance in somatic embryos," In Vitro
Development in Biology, vol. 26, pp.85-90, 1990.
[2] T. Senaratna, "Artificial seeds," Biotechnology Advancement, vol. 10,
pp.379-392, 1992.
[3] J. A. Fuji, D. Slade and K. Redenbaugh, "Planting artificial seeds and
somatic embryos," in Synseeds: application of synthetic seeds to crop
improvement, K Redenbaugh, Ed. Boca Raton, FL: CRC Press, 1993.
[4] T. Senaratna, B. D. McKersieand S. R. Bowley, "Desiccation tolerance
of alfalfa (Medicago sativa L.) somatic embryos. Influence of abscisic
acid, stress pretreatments and drying rates," Plant Science, vol. 65, pp.
253-259, 1989.
[5] D. Greig, The Handbook of Australian flowers for the garden and home.
East Roseville, NSW, Australia: Simon & Schuster Australia, 1993, pp.
70-71.
[6] P. L. Bhalla and K. Sweeney, "Direct in vitro regeneration of the
Australian fan flower, Scaevola R. Br.," Scientia Horticulturae, vol. 79,
pp. 65-74, 1999.
[7] P. L. Bhalla and H. Xu, "Plant regeneration from callus of Australian fan
flower, Scaevola,".Journal of Plant Physiology, vol. 154, pp. 374-378,
1999.
[8] Y. H. Wang and P. L. Bhalla, "Somatic embryogenesis from leaf
explants of Australian fan flower, Scaevola aemula R. Br.," Plant Cell
Reports, vol. 22, pp. 408-414, 2004.
[9] Yu-Hua, Wang and P. L. Bhalla, "Plant regeneration from cell
suspensions initiated from leaf- and root- derived calli of the Australian
ornamental plant Scaevola aemula R. Br.," Propagation of Ornamental
Plants, vol. 6, pp. 55-60, 2006.
[10] M. Vajrabhaya, "Embryogenesis," in Cell and Tissue Culture in Field
Crop Improvement,. No. 38, M. Vajrabhaya. Ed. Food and Fertilizer
Technology Centre Book Series, 1988, pp. 24-32.
[11] P. Castillo, J. Marquez, A. Rubluo, G. Hernandez and M. Lara, "Plant
regeneration from callus and suspension cultures of Valeriana edulis
ssp. Procera via simultaneous organogenesis and somatic
embryogenesis," Plant Science, vol. 151, pp. 115-119,2000.
[12] J. L.Zimmerman, "Somatic embryogenesis: a model for early
development in higher plants," The Plant Cell ,vol. 5, pp. 1411-1423,
1993.
[13] A. N. Binns, "Cytokinin accumulation and action: Biochemical, genetic
and molecular approaches," Annual Review of Plant Physiology , vol.
45, pp. 73-196, 1994.
[14] T. Badzian, G. R. Hennen and J. Fotyma-Kern, "In vitro rooting of
clonal propagated miniature rose cultivars,"ISHS Acta Horticulturae,
vol. 289, pp. 329-330, 1991.
[15] Z. A. Sajid and F. Aftab, "Effect of Thidiazuron (TDZ) on in vitro
micropropagation of Solanum tuberosum L. cvs. Desiree and Cardinal,"
Pakistan Journal of Botany, vol. 41, pp. 1811-1815, 2009.
[16] M. I. Hutchinson, R. S. Krishma and P. K. Saxena, "Morphological and
physiological changes during thiadiazuron induced somatic
embryogenesis in geranium (Pelargonium hortorum L.) hypocotyl
culture,". International Journal of Plant Science, vol. 157, pp. 110-117,
1996.
[17] R. Gill,J. M. Gerrath and P. K. Saxena, "High frequency direct somatic
embryogenesis in thin layer cultures of hybrid seed geranium
(Pelargonium hortorum L.)," Canadian Journal of Botany, vol. 71, pp.
408-413, 1993.
[18] L. Radojevic, O. Sokic and B. Tucic, "Somatic embryogenesis in tissue
culture of iris (Iric pumila L.)," Acta Horticulturae, vol. 212, pp. 719-
723, 1987.
[19] C. Visser, J. A. Qureshi, R. Grill, K. A. Malik and P. K. Saxena,
"Morpho-regulatory role of thidiazuron: Submission of auxin and
cytokinin requirement for the induction of somatic embryogenesis in
geranium hypocotyls culture," Plant Physiology, vol. 99, pp. 1704-1707,
1992.
[20] T. Murashige and F. Skoog, "A revised medium for rapid growth and
bioassay with tobacco tissue cultures,"Physiologia Plantarum, vol. 115,
pp. 493-497, 1962.
[21] K. Tanaka, Y. Kanno, S. Kudo and M. Suzuki, "Somatic embryogenesis
and plant regeneration in Chrysanthemum (Dendranthem grandiflorum
(Ramat) Kitamura," Plant Cell Reports, vol. 19, pp. 946-953, 2000.
[22] S. Sushmakumari, K. Rekha, V. Thomas, S. Sobha and R. Jayasree,
"Multiple shoot formation from somatic embryos of Hevea brasiliensis
(Muell) Arg.," Indian Journal of Natural Rubber Research, vol. 12, pp.
23-28, 1999.
[23] C. Visser-Tenyenhuis, B. N. S. Murthy and J. Odumeru, "Modulation of
somatic embryogenesis in hypocotyls-derived cultures of geranium
(Pelagonium x hortorum Bailey) cv Ringo Rose by a bacterium," In
Vitro Cellular & Developmental. Biology - Plant, vol. 30, pp. 140-
143,1994.
[24] A. B. Martin, Y. Cuadrado, H. Guerra, P. Gallego, O. Hita, L. Martin, A.
Dorado and N. Villalobos, "Differences in the contents of total sugars,
reducing sugars, starch and sucrose in embryogenic and nonembryogenic
calli from Medicago arborea L.," Plant Science, vol. 154,
pp. 143-151, 2000.
[25] M. G. Taylor and I. K. Vasil, "The ultrastructure of somatic embryo
development in pearl millet (Pennsisetum glaucum; Poaceae),"
American Journal of Botany, vol. 83, pp. 28-44, 1996.
[26] Z. Ipekci and N. Gozukirmizi, "Indirect somatic embryogenesis and
plant regeneration from leaf and internode explants of Paulownia
elongate," Plant Cell Tissue and Organ Culture, vol. 79, pp. 341-345,
2005.
[27] H. K. Neumann, "Some studies on somatic embryogenesis, a tool in
plant biotechnology,"http://bibd.uni-giessen.de/gdoc/2000/p000004.pdf.,
2000.
[28] U. B. Barwale, H. R. Kerns and J. M. Widholm, "Plant regeneration
from callus cultures of several soybean genotypes via embryogenesis
and organogenesis," Planta, vol. 167, pp. 473-481, 1986.
[29] C. E. Van Schaik, A. Posthuma, M. J. De Jeu and E. Jacobsen, "Plant
regeneration through somatic embryogenesis from callus induced on
immature embryos of Alstroemeria spp. L.," Plant Cell Reports, vol. 15,
pp. 377-380, 1996.
[30] H. S. Lin, M. J. De Jeu and E. Jacobsen, "Development of a plant
regeneration system based on friable embryogenic callus in the
ornamental Alstroemeria," Plant Cell Reports, vol. 19, pp. 529-534,
2000.
[1] T. Senaratna, B. D. McKersie and S. R. Bowley, "Artificial seeds:
Induction of desiccation tolerance in somatic embryos," In Vitro
Development in Biology, vol. 26, pp.85-90, 1990.
[2] T. Senaratna, "Artificial seeds," Biotechnology Advancement, vol. 10,
pp.379-392, 1992.
[3] J. A. Fuji, D. Slade and K. Redenbaugh, "Planting artificial seeds and
somatic embryos," in Synseeds: application of synthetic seeds to crop
improvement, K Redenbaugh, Ed. Boca Raton, FL: CRC Press, 1993.
[4] T. Senaratna, B. D. McKersieand S. R. Bowley, "Desiccation tolerance
of alfalfa (Medicago sativa L.) somatic embryos. Influence of abscisic
acid, stress pretreatments and drying rates," Plant Science, vol. 65, pp.
253-259, 1989.
[5] D. Greig, The Handbook of Australian flowers for the garden and home.
East Roseville, NSW, Australia: Simon & Schuster Australia, 1993, pp.
70-71.
[6] P. L. Bhalla and K. Sweeney, "Direct in vitro regeneration of the
Australian fan flower, Scaevola R. Br.," Scientia Horticulturae, vol. 79,
pp. 65-74, 1999.
[7] P. L. Bhalla and H. Xu, "Plant regeneration from callus of Australian fan
flower, Scaevola,".Journal of Plant Physiology, vol. 154, pp. 374-378,
1999.
[8] Y. H. Wang and P. L. Bhalla, "Somatic embryogenesis from leaf
explants of Australian fan flower, Scaevola aemula R. Br.," Plant Cell
Reports, vol. 22, pp. 408-414, 2004.
[9] Yu-Hua, Wang and P. L. Bhalla, "Plant regeneration from cell
suspensions initiated from leaf- and root- derived calli of the Australian
ornamental plant Scaevola aemula R. Br.," Propagation of Ornamental
Plants, vol. 6, pp. 55-60, 2006.
[10] M. Vajrabhaya, "Embryogenesis," in Cell and Tissue Culture in Field
Crop Improvement,. No. 38, M. Vajrabhaya. Ed. Food and Fertilizer
Technology Centre Book Series, 1988, pp. 24-32.
[11] P. Castillo, J. Marquez, A. Rubluo, G. Hernandez and M. Lara, "Plant
regeneration from callus and suspension cultures of Valeriana edulis
ssp. Procera via simultaneous organogenesis and somatic
embryogenesis," Plant Science, vol. 151, pp. 115-119,2000.
[12] J. L.Zimmerman, "Somatic embryogenesis: a model for early
development in higher plants," The Plant Cell ,vol. 5, pp. 1411-1423,
1993.
[13] A. N. Binns, "Cytokinin accumulation and action: Biochemical, genetic
and molecular approaches," Annual Review of Plant Physiology , vol.
45, pp. 73-196, 1994.
[14] T. Badzian, G. R. Hennen and J. Fotyma-Kern, "In vitro rooting of
clonal propagated miniature rose cultivars,"ISHS Acta Horticulturae,
vol. 289, pp. 329-330, 1991.
[15] Z. A. Sajid and F. Aftab, "Effect of Thidiazuron (TDZ) on in vitro
micropropagation of Solanum tuberosum L. cvs. Desiree and Cardinal,"
Pakistan Journal of Botany, vol. 41, pp. 1811-1815, 2009.
[16] M. I. Hutchinson, R. S. Krishma and P. K. Saxena, "Morphological and
physiological changes during thiadiazuron induced somatic
embryogenesis in geranium (Pelargonium hortorum L.) hypocotyl
culture,". International Journal of Plant Science, vol. 157, pp. 110-117,
1996.
[17] R. Gill,J. M. Gerrath and P. K. Saxena, "High frequency direct somatic
embryogenesis in thin layer cultures of hybrid seed geranium
(Pelargonium hortorum L.)," Canadian Journal of Botany, vol. 71, pp.
408-413, 1993.
[18] L. Radojevic, O. Sokic and B. Tucic, "Somatic embryogenesis in tissue
culture of iris (Iric pumila L.)," Acta Horticulturae, vol. 212, pp. 719-
723, 1987.
[19] C. Visser, J. A. Qureshi, R. Grill, K. A. Malik and P. K. Saxena,
"Morpho-regulatory role of thidiazuron: Submission of auxin and
cytokinin requirement for the induction of somatic embryogenesis in
geranium hypocotyls culture," Plant Physiology, vol. 99, pp. 1704-1707,
1992.
[20] T. Murashige and F. Skoog, "A revised medium for rapid growth and
bioassay with tobacco tissue cultures,"Physiologia Plantarum, vol. 115,
pp. 493-497, 1962.
[21] K. Tanaka, Y. Kanno, S. Kudo and M. Suzuki, "Somatic embryogenesis
and plant regeneration in Chrysanthemum (Dendranthem grandiflorum
(Ramat) Kitamura," Plant Cell Reports, vol. 19, pp. 946-953, 2000.
[22] S. Sushmakumari, K. Rekha, V. Thomas, S. Sobha and R. Jayasree,
"Multiple shoot formation from somatic embryos of Hevea brasiliensis
(Muell) Arg.," Indian Journal of Natural Rubber Research, vol. 12, pp.
23-28, 1999.
[23] C. Visser-Tenyenhuis, B. N. S. Murthy and J. Odumeru, "Modulation of
somatic embryogenesis in hypocotyls-derived cultures of geranium
(Pelagonium x hortorum Bailey) cv Ringo Rose by a bacterium," In
Vitro Cellular & Developmental. Biology - Plant, vol. 30, pp. 140-
143,1994.
[24] A. B. Martin, Y. Cuadrado, H. Guerra, P. Gallego, O. Hita, L. Martin, A.
Dorado and N. Villalobos, "Differences in the contents of total sugars,
reducing sugars, starch and sucrose in embryogenic and nonembryogenic
calli from Medicago arborea L.," Plant Science, vol. 154,
pp. 143-151, 2000.
[25] M. G. Taylor and I. K. Vasil, "The ultrastructure of somatic embryo
development in pearl millet (Pennsisetum glaucum; Poaceae),"
American Journal of Botany, vol. 83, pp. 28-44, 1996.
[26] Z. Ipekci and N. Gozukirmizi, "Indirect somatic embryogenesis and
plant regeneration from leaf and internode explants of Paulownia
elongate," Plant Cell Tissue and Organ Culture, vol. 79, pp. 341-345,
2005.
[27] H. K. Neumann, "Some studies on somatic embryogenesis, a tool in
plant biotechnology,"http://bibd.uni-giessen.de/gdoc/2000/p000004.pdf.,
2000.
[28] U. B. Barwale, H. R. Kerns and J. M. Widholm, "Plant regeneration
from callus cultures of several soybean genotypes via embryogenesis
and organogenesis," Planta, vol. 167, pp. 473-481, 1986.
[29] C. E. Van Schaik, A. Posthuma, M. J. De Jeu and E. Jacobsen, "Plant
regeneration through somatic embryogenesis from callus induced on
immature embryos of Alstroemeria spp. L.," Plant Cell Reports, vol. 15,
pp. 377-380, 1996.
[30] H. S. Lin, M. J. De Jeu and E. Jacobsen, "Development of a plant
regeneration system based on friable embryogenic callus in the
ornamental Alstroemeria," Plant Cell Reports, vol. 19, pp. 529-534,
2000.
@article{"International Journal of Biological, Life and Agricultural Sciences:52342", author = "Shyama Ranjani Weerakoon", title = "Direct and Indirect Somatic Embryogenesis from Petiole and Leaf Explants of Purple Fan Flower (Scaevola aemula R. Br. cv. 'Purple Fanfare')", abstract = "Direct and indirect somatic embryogenesis (SE) from
petiole and leaf explants of Scaevola aemula R. Br. cv. 'Purple
Fanfare' was achieved. High frequency of somatic embryos was
obtained directly from petiole and leaf explants using an inductive
plant growth regulator signal thidiazuron (TDZ). Petiole explants
were more responsive to SE than leaves. Plants derived from somatic
embryos of petiole explants germinated more readily into plants. SE
occurred more efficiently in half-strength Murashige and Skoog
(MS) medium than in full-strength MS medium. Non-embryogenic
callus induced by 2, 4-dichlorophenoxyacetic acid was used to
investigate the feasibility of obtaining SE with TDZ as a secondary
inductive plant growth regulator (PGR) signal. Non-embryogenic
callus of S. aemula was able to convert into an “embryogenic
competent mode" with PGR signal. Protocol developed for induction
of direct and indirect somatic embryogenesis in S. aemula can
improve the large scale propagation system of the plant in future.", keywords = "Petiole and leaf explants, Scaevola aemula, Somaticembryogenesis", volume = "4", number = "5", pages = "235-9", }
