An Efficient Protocol for Cyclic Somatic Embryogenesis in Neem (Azadirachta indica A Juss.)
Neem is a highly heterozygous and commercially
important perennial plant. Conventionally, it is propagated by seeds
which loose viability within two weeks. Strictly cross pollinating
nature of the plant causes serious barrier to the genetic improvement
by conventional methods. Alternative methods of tree improvement
such as somatic hybridization, mutagenesis and genetic
transformation require an efficient in vitro plant regeneration system.
In this regard, somatic embryogenesis particularly secondary somatic
embryogenesis may offer an effective system for large scale plant
propagation without affecting the clonal fidelity of the regenerants. It
can be used for synthetic seed production, which further bolsters
conservation of this tree species which is otherwise very difficult
The present report describes the culture conditions necessary to
induce and maintain repetitive somatic embryogenesis, for the first
time, in neem. Out of various treatments tested, the somatic embryos
were induced directly from immature zygotic embryos of neem on
MS + TDZ (0.1 μM) + ABA (4 μM), in more than 76 % cultures.
Direct secondary somatic embryogenesis occurred from primary
somatic embryos on MS + IAA (5 μM) + GA3 (5 μM) in 12.5 %
cultures. Embryogenic competence of the explant as well as of the
primary embryos was maintained for a long period by repeated
subcultures at frequent intervals. A maximum of 10 % of these
somatic embryos were converted into plantlets.
[1] C.J.J.M. Raemakers, E. Jacobsen, and R.G.F. Visser, Secondary somatic
embryogenesis and application in plant breeding. Euphytica, 1995, 81:
93-107.
[2] S.A. Merkle, W.A. Parrott, and E.G. Williams, Applications of somatic
embryogenesis and embryo cloning. In: Bhojwani SS (ed) Plant tissue
culture: applications and limitations. Elsevier, Amsterdam, 1990, pp 67-
101.
[3] C. Akula, A. Akula, and R. Drew, Somatic embryogenesis in clonal
neem, Azadirachta indica A. Juss. and analysis for in vitro azadirachtin
production. In Vitro Cell Dev-Pl., 2003, 39:304-310.
[4] R. Chaturvedi., M.K. Razdan, and S.S. Bhojwani, In vitro
morphogenesis in zygotic embryo cultures of neem (Azadirachta indica
A. Juss.) Plant Cell Rep., 2004, 22:801-809.
[5] A. Gairi, and A. Rashid, Direct differentiation of somatic embryos on
different regions of intact seedlings of Azadirachta in response to
thidiazuron. J. Plant Physiol., 2004a, 161:1073-1077.
[6] Gyana Ranjan Rout, In vitro somatic embryogenesis in callus cultures of
Azadirachta indica A. Juss.ÔÇöa multipurpose tree. J. For. Res., 2005,
10:263-267.
[7] T. Murashige, and F. Skoog, A revised medium for rapid growth and
bioassays with tobacco tissue cultures. - Physiol. Plant, 1962, 15: 473-
497.
[8] E.G. Williams, and G. Maheswaran, Somatic embryogenesis: factors
influencing coordinated behaviour of cells as an embryogenic group.
Ann. Bot., 1986, 57:443-462.
[9] O. Karami, A. Deljou, and A.M. Pour, Repetitive somatic embryogenesis
in carnation on picloram supplemented media. Plant Growth Regul.,
2007, 51:33-39.
[10] R.R. Nair, and S.D. Gupta, High-frequency plant regeneration through
cyclic secondary somatic embryogenesis in black pepper (Piper nigrum
L.) Plant Cell Rep., 2006, 24: 699-707.
[11] S. Agarwal, K. Kanwar, and D.R. Sharma, Factors affecting secondary
somatic embryogenesis and embryo maturation in Morus alba L. Sci.
Hort., 2004, 102: 359-368.
[12] P. Giridhar, E.P. Indu, G.A. Ravishankar and A. Chandrasekar, Influence
of triacontanol on somatic embryogenesis in Coffea arabica L. and
Coffea canephora P. ex. Fr. In Vitro Cell Dev Biol Plant, 2004, 40:200-
203.
[13] J.-T, Chen, and W.-C. Chang, Induction of repetitive embryogenesis
from seed-derived protocorms of Phalaenopsis amabilis var. Formosa
Shimadzu. In Vitro Cell Dev Biol Plant, 2004, 40:290-293.
[14] E.L, Little, Z.V. Magbanua, and W.A. Parrott, A protocol for repetitive
somatic embryogenesis from mature peanut epicotyls. Plant Cell Rep.,
2000, 19:351-357.
[15] L.O. das Neves, S.R.L. Duque, J.S. de Almeida and P.S. Fevereiro,
Repetitive somatic embryogenesis in Medicago truncatula sp.
Narbonensis and M. truncatula Gaertn cv. Jemalong. Plant Cell Rep.,
1999, 18:398-405.
[16] R. Parra, and J.B. Amo-Marco, Secondary somatic embryogenesis and
plant regeneration in myrtle (Myrtus communis L.). Plant Cell Rep.,
1998, 18:325-330.
[17] P. Das, S. Samantaray, A.V. Roberts, and G.R, Rout, In vitro somatic
embryogenesis of Dalbergia sisoo Roxb.ÔÇöa multipurpose timberyielding
tree. Plant Cell Rep., 1997, 16:578-582.
[18] G. Daigny, H. Paul, R.S. Sangwan, and B.S. Sangwan-Narreel, Factors
influencing secondary somatic embryogenesis in Malus x domestica
Borkh. (cv. ÔÇÿGloster 69-). Plant Cell Rep., 1996, 16:153-157.
[19] F. Carimi, F. De Pasquale, and F.G. Crescimanno, Somatic
embryogenesis and plant regeneration from pistil thin cell layers of
Citrus. Plant Cell Rep., 1999, 18:935-940.
[20] J.-T, Chen, and W.-C. Chang, Effect of auxins and cytokinins on direct
somatic embryogenesis on leaf explants of Oncidium ÔÇÿ Gower Ramsey-.
Plant Growth Regul., 2001, 34: 229-232.
[21] D. calic, S. Zdravkovic-Korac, and Lj. Radojevic, Secondary
embryogenesis in androgenic embryo cultures of Aesculus
hippocastanum L. Biol. Plant, 2005, 49:435-438.
[22] P. Pui Puigderrajols, C. Celestino, M. Sulis, M. Toribio, and M.
Molinas,. Histology of organogenic and embryogenic responses in
cotyledons of somatic embryos of Quercus suber L. Int. J. Plant Sci.,
2000, 161: 353-362.
[23] W.W. Su, W.I. Hwang, S.Y. Kim, and Y. Sagawa, Induction of somatic
embryogenesis in Azadirachta indica. Plant Cell Tissue Organ Cult.,
1997, 50:91-95.
[1] C.J.J.M. Raemakers, E. Jacobsen, and R.G.F. Visser, Secondary somatic
embryogenesis and application in plant breeding. Euphytica, 1995, 81:
93-107.
[2] S.A. Merkle, W.A. Parrott, and E.G. Williams, Applications of somatic
embryogenesis and embryo cloning. In: Bhojwani SS (ed) Plant tissue
culture: applications and limitations. Elsevier, Amsterdam, 1990, pp 67-
101.
[3] C. Akula, A. Akula, and R. Drew, Somatic embryogenesis in clonal
neem, Azadirachta indica A. Juss. and analysis for in vitro azadirachtin
production. In Vitro Cell Dev-Pl., 2003, 39:304-310.
[4] R. Chaturvedi., M.K. Razdan, and S.S. Bhojwani, In vitro
morphogenesis in zygotic embryo cultures of neem (Azadirachta indica
A. Juss.) Plant Cell Rep., 2004, 22:801-809.
[5] A. Gairi, and A. Rashid, Direct differentiation of somatic embryos on
different regions of intact seedlings of Azadirachta in response to
thidiazuron. J. Plant Physiol., 2004a, 161:1073-1077.
[6] Gyana Ranjan Rout, In vitro somatic embryogenesis in callus cultures of
Azadirachta indica A. Juss.ÔÇöa multipurpose tree. J. For. Res., 2005,
10:263-267.
[7] T. Murashige, and F. Skoog, A revised medium for rapid growth and
bioassays with tobacco tissue cultures. - Physiol. Plant, 1962, 15: 473-
497.
[8] E.G. Williams, and G. Maheswaran, Somatic embryogenesis: factors
influencing coordinated behaviour of cells as an embryogenic group.
Ann. Bot., 1986, 57:443-462.
[9] O. Karami, A. Deljou, and A.M. Pour, Repetitive somatic embryogenesis
in carnation on picloram supplemented media. Plant Growth Regul.,
2007, 51:33-39.
[10] R.R. Nair, and S.D. Gupta, High-frequency plant regeneration through
cyclic secondary somatic embryogenesis in black pepper (Piper nigrum
L.) Plant Cell Rep., 2006, 24: 699-707.
[11] S. Agarwal, K. Kanwar, and D.R. Sharma, Factors affecting secondary
somatic embryogenesis and embryo maturation in Morus alba L. Sci.
Hort., 2004, 102: 359-368.
[12] P. Giridhar, E.P. Indu, G.A. Ravishankar and A. Chandrasekar, Influence
of triacontanol on somatic embryogenesis in Coffea arabica L. and
Coffea canephora P. ex. Fr. In Vitro Cell Dev Biol Plant, 2004, 40:200-
203.
[13] J.-T, Chen, and W.-C. Chang, Induction of repetitive embryogenesis
from seed-derived protocorms of Phalaenopsis amabilis var. Formosa
Shimadzu. In Vitro Cell Dev Biol Plant, 2004, 40:290-293.
[14] E.L, Little, Z.V. Magbanua, and W.A. Parrott, A protocol for repetitive
somatic embryogenesis from mature peanut epicotyls. Plant Cell Rep.,
2000, 19:351-357.
[15] L.O. das Neves, S.R.L. Duque, J.S. de Almeida and P.S. Fevereiro,
Repetitive somatic embryogenesis in Medicago truncatula sp.
Narbonensis and M. truncatula Gaertn cv. Jemalong. Plant Cell Rep.,
1999, 18:398-405.
[16] R. Parra, and J.B. Amo-Marco, Secondary somatic embryogenesis and
plant regeneration in myrtle (Myrtus communis L.). Plant Cell Rep.,
1998, 18:325-330.
[17] P. Das, S. Samantaray, A.V. Roberts, and G.R, Rout, In vitro somatic
embryogenesis of Dalbergia sisoo Roxb.ÔÇöa multipurpose timberyielding
tree. Plant Cell Rep., 1997, 16:578-582.
[18] G. Daigny, H. Paul, R.S. Sangwan, and B.S. Sangwan-Narreel, Factors
influencing secondary somatic embryogenesis in Malus x domestica
Borkh. (cv. ÔÇÿGloster 69-). Plant Cell Rep., 1996, 16:153-157.
[19] F. Carimi, F. De Pasquale, and F.G. Crescimanno, Somatic
embryogenesis and plant regeneration from pistil thin cell layers of
Citrus. Plant Cell Rep., 1999, 18:935-940.
[20] J.-T, Chen, and W.-C. Chang, Effect of auxins and cytokinins on direct
somatic embryogenesis on leaf explants of Oncidium ÔÇÿ Gower Ramsey-.
Plant Growth Regul., 2001, 34: 229-232.
[21] D. calic, S. Zdravkovic-Korac, and Lj. Radojevic, Secondary
embryogenesis in androgenic embryo cultures of Aesculus
hippocastanum L. Biol. Plant, 2005, 49:435-438.
[22] P. Pui Puigderrajols, C. Celestino, M. Sulis, M. Toribio, and M.
Molinas,. Histology of organogenic and embryogenic responses in
cotyledons of somatic embryos of Quercus suber L. Int. J. Plant Sci.,
2000, 161: 353-362.
[23] W.W. Su, W.I. Hwang, S.Y. Kim, and Y. Sagawa, Induction of somatic
embryogenesis in Azadirachta indica. Plant Cell Tissue Organ Cult.,
1997, 50:91-95.
@article{"International Journal of Biological, Life and Agricultural Sciences:61607", author = "Mithilesh Singh and Rakhi Chaturvedi", title = "An Efficient Protocol for Cyclic Somatic Embryogenesis in Neem (Azadirachta indica A Juss.)", abstract = "Neem is a highly heterozygous and commercially
important perennial plant. Conventionally, it is propagated by seeds
which loose viability within two weeks. Strictly cross pollinating
nature of the plant causes serious barrier to the genetic improvement
by conventional methods. Alternative methods of tree improvement
such as somatic hybridization, mutagenesis and genetic
transformation require an efficient in vitro plant regeneration system.
In this regard, somatic embryogenesis particularly secondary somatic
embryogenesis may offer an effective system for large scale plant
propagation without affecting the clonal fidelity of the regenerants. It
can be used for synthetic seed production, which further bolsters
conservation of this tree species which is otherwise very difficult
The present report describes the culture conditions necessary to
induce and maintain repetitive somatic embryogenesis, for the first
time, in neem. Out of various treatments tested, the somatic embryos
were induced directly from immature zygotic embryos of neem on
MS + TDZ (0.1 μM) + ABA (4 μM), in more than 76 % cultures.
Direct secondary somatic embryogenesis occurred from primary
somatic embryos on MS + IAA (5 μM) + GA3 (5 μM) in 12.5 %
cultures. Embryogenic competence of the explant as well as of the
primary embryos was maintained for a long period by repeated
subcultures at frequent intervals. A maximum of 10 % of these
somatic embryos were converted into plantlets.", keywords = "Azadirachta indica A. Juss., Cytokinin, Somatic
embryogenesis, zygotic embryo culture.", volume = "3", number = "3", pages = "162-3", }
