Bhargava Neha1*, Gomase V.S.2
1Padmashree Dr. D.Y. Patil University, Navi Mumbai, 400614, India
2School of Technology, S.R.T.M. University, Sub-Centre, Latur, 413512, India
* Corresponding Author : nehabhargava205@gmail.com
Received : - Accepted : - Published : 21-12-2010
Volume : 1 Issue : 2 Pages : 15 - 21
Int J Mol Biol 1.2 (2010):15-21
DOI : http://dx.doi.org/10.9735/0976-0482.1.2.15-21
Keywords : Metabolic diversity, Transcriptome, Genome, Gene expression, Stress tolerance
Conflict of Interest : None declared
Metabolic diversity in various plants of various kingdoms and species has successfully solved many fundamental questions arising due to different and varying growth conditions and parameters they are subjected to. It is important to study metabolic diversity to understand how science has evolved and succeeded to address the practical application of recombinant DNA technology for the benefit of plants themselves and also to know how these metabolic changes help them adapt to diverse conditions.
[1] Qi X., Bakht S., Leggett M., et al.
(2004) PNAS, 101(21), 8233-8238
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[2] Harrigan, George G., Martino-Catt, et
al. (2007) Metabolomics, 3(3), 259-
272.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[3] Metabolism course notes. Author:
Michael Palmer, University of
Waterloo.
http://watcut.uwaterloo.ca/webnotes/M
etabolism/page-1.3.html
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[4] Thomas Thiel, Andreas Graner,
Robbie Waugh, et al. (2009) BMC
Evol Biol., 9: 209
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[5] David Honys and David Twell (2003)
Plant Physiol., 132(2), 640–652
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[6] Dong Ju Lee, Jong Wha Park, Han
Woo Lee, et al. (2009) J. Exp. Bot., 60
(13), 3935-3957
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[7] Peter Breyne, Rozemarijn Dreesen,
Klaas Vandepoele. (2002) PNAS,
99(23), 14825-14830
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[8] Hirt Heribert, Shinozaki. (2004) Topics
in current genetics
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[9] Margarete Baier, Andrea Kandlbinder,
Karl-Josef Dietz, et al. (2004) Plant
Responses to Abiotic Stress Topics in
Current Genetics, 4, 271-308
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[10] Thomashow M. F. (1990) Annu. Rev.
Plant Physiol. Plant Mol. Biol. 50,
571–599
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[11] Seki M., Kamei A., Yamaguchi-
Shinozaki K., Shinozaki K. (2003)
Curr. Opin. Biotechnol. 14: 194–199
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[12] Essaid Ait Barka, Jerzy Nowak, and
Christophe Clement. (2006) Applied
and environmental microbiology,
72(11), 7246–7252
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[13] Han Song Hee, Cho Song Mi,
Oh, Sang A, et al. (2009) American
society of plant biologists, Plant
Biology
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[14] Isabel M. López-Lara, Christian
Sohlenkamp, and Geiger. (2003)
MPMI, 16(7), 567–579
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[15] Rojas-Jiménez K, Sohlenkamp C,
Geiger O, et al. (2005) Mol Plant
Microbe Interact., 18 (11), 1175-1185
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[16] Christian Sohlenkamp, Kanaan A.
Galindo-Lagunas, Ziqiang Guan, et al.
(2007) APS journal, 20(11), 1421-
1430
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[17] Ran Lifshitz, Joseph W. Kloepper,
Fran M. Scher, et al. (1986) Applied
and environmental microbiology,
51(2), 251-255
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[18] Neil p. J. Price, Theresa M. Kelly,
Christian R. H. Raetz. (1994) Journal
Of Bacteriology, 176(15), 4646-4655
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[19] Christoph Kneip, Peter Lockhart,
Christine Voß, et al. (2007) BMC
Evolutionary Biology
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[20] Roche P, Debellé F, Maillet F, et al.
(1991). Cell, 67(6), 1131-1143.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[21] Tian Chunjie, Shachar-Hill,
Yair. (2009) American society of
plant biologists, Plant Biology
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[22] Australian National Botanic Gardens,
Australian
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[23] Nomura Mika, Arunothayanan Hatthay,
Dao, Tan Van, et al. (2009) American
society of plant biologists, Plant
Biology
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[24] Luke Flory S. and Brett Mattingly W.
(2008) Oecologia, Vol. 156, No. 3,
Pages 649-656
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[25] Alexander Boyko, Palak Kathiria,
Franz J. Zemp, et al. (2007) Nucleic
Acids Res., 35(5): 1714–1725
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[26] Braam J., Sistrunk M.L., Polisensky
D.H., et al. (1997) Planta, 203: S35-
S41
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[27] Tahat M.M., Kamaruzaman , Sijam
and Othman R.(2010) Plant Pathology
Journal, 9(4), 198-207
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[28] Keith L. Adams and Jonathan F.
Wendel. (2005) TRENDS in Genetics,
21(10), 539-543
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[29] Sundaresan V., Springer P., Volpe T.,
(1995) Genes & Dev., 9, 1797-1810
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[30] Brian K. Harper and C. Neal Stewart.
(2000) Plant Molecular Biology
Reporter 18: Page: 141.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[31] Simplot Company J.R. (2004) Trends
in Plant Science, 9(9), 457-464
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[32] Gustavo A. de la Riva, Joel González-
Cabrera, Roberto Vázquez-Padrón, et
al. (1998) EJB Electronic Journal of
Biotechnology, 1, 3
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[33] Sang-Min Chung, Manjusha Vaidya
and Tzvi Tzfira. (2006) Trends in plant
science, 11(1), 1-4.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[34] Chawla H.S. (2002) Science
Publishers, 376-377.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[35] Dexi Liu, Evelyn F. Chia, Hui Tian
(2003) Chemical Methods for DNA
Delivery: An Overview, Gene Delivery
to Mammalian Cells: Volume 1:
Nonviral Gene Transfer Techniques,
Series: Methods in Molecular Biology,
245, 3-23.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[36] Jaideep Mathur and Csaba Koncz.
PEG-Mediated Protoplast
Transformation with Naked DNA,
Methods in Molecular Biology, Vol. 82:
Arabidopsis Protocols, 267-276
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[37] Crossway Anne, Facciotti Daniel
(1988) Plant cell microinjection
technique.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[38] Sally L. Van Wert and James A.
Saunders. (1992) Plant Physiol.,
99(2), 365–367.
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[39] Paul Christou, Dennis McCabe (1992)
Particle Gun Transformation of Crop
Plants Using Electric Discharge
(ACCELL™ Technology), Published in
Probe, 2 (2).
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[40] Mohammed S. Al-Dosari and Xiang
Gao. (2009) AAPS J., 11(4), 671–681
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus
[41] Maria Laura Immordino, Franco
Dosio, and Luigi Cattel. (2006) Int J
Nanomedicine., 1(3), 297–315
» CrossRef » Google Scholar » PubMed » DOAJ » CAS » Scopus