Simulation of Increased Ambient Ozone to Estimate Nutrient Content and Genetic Change in Two Thai Soybean Cultivars
This research studied the simulation of increased
ambient ozone to estimate nutrient content and genetic changes in
two Thai soybean cultivars (Chiang Mai 60 and Srisumrong 1).
Ozone stress conditions affected proteins and lipids. It was found
that proteins decreased, but lipids increased. Srisumrong 1 cultivars
were more sensitive to ozone stress than Chiang Mai 60 cultivars.
The effect of ozone stress conditions on plant phenotype and
genotype was analyzed using the AFLP technique for the 2 Thai
soybean cultivars (Chiang Mai 60 and Srisumrong 1).
[1] L. Leitao, P. Goulas, and J. Biolley, "Time-course of Rubisco oxidation
in baen (Phaseolus vulgaris L.)," Plant SCI, vol. 30, 2003, pp. 1-8..
[2] S.J. Oltmans, A.S. Lefohn, J.M. Harris, I. Galbally, H.E. Scheel, G.
Bodeker, E. Brunke, H. Claude, D. Tarasick, B.J. Johnson, P.
Simmonds, D. Shadwick, K. Anlaf, K. Hayden, F. Schmidlin, T.
Fujimoto, and H.E. Cuevas. "Long term changes in tropospheric ozone,"
Atmos Environ, vol. 40, 2006, pp. 3156-3173.
[3] E. Singh, S. Tiwari, and M. Agrawal,."Variability in antioxidant and
metabolite levels, growth and yield of two soybean varieties: An
assessment of anticipated yield losses under projected elevation of
ozone," Agr Ecosyst Environ, vol. 135, 2010, pp. 168-177.
[4] J.E. Miller, F.L. Booker, E.L. Ficus, A.S. Heagle, W.A. Pursley, S.F.
Vozzo, and W.W. Heck,. "Ultraviolet-B Radiation and Ozone Effects
on Growth, Yield, and Photosynthesis of Soybean," J Environ Qual,
vol. 23, 1994, pp. 83-91.
[5] A.S. Heagle. Ozone and Crop Yield. Annu Rev Phytopathol, vol. 27,
1989, pp. 397-423.
[6] http://www.pcd.or.th. Pollution Control Department of Thailand. 2004.
[7] H.B. Krishnan. "Biochemistry and molecular biology of soybean seed
storage proteins," J New Seeds, vol. 2, 2000, pp. 1-25.
[8] H. B. Krishnan. "Engineering soybean for enhanced sulfur amino acid
content," Crop Sci, vol. 45, 2005, pp. 454-461.
[9] N. C. Nielsen, R. Bassusner, and T. Beaman. The biochemistry and cell
biology of embryo storage proteins. In R. A. Larkins & I. K. Vasil
(Eds.), Cellular and molecular biology of plant seed development (pp.
151-220). Dordrecht: Kluwer Academic Publishers. 1997
[10] T. J. Brumm, and C. R. Jr. Hurburgh. "Quality of the 2002 soybean crop
from the United States," Louis, MO: American Soybean Association.
2002
[11] C. G. Zarkadas, Z.-R. Yu, H. D. Voldeng, and A. Minero-Amador.
"Assessment of the protein quality of a new high-protein soybean
cultivar by amino acid analysis," J Agr Food Chem, vol. 41, 1993, pp.
616-623.
[12] C. G. Zarkadas, H. D. Voldeng, Z.-R. Yu, and V. Choi. "Assessment of
the protein quality of nine northern adapted yellow and brown seed
coated soybean cultivars by amino acid analysis," J Agr Food Chem,
vo.l 47, 1999, pp. 5009-5018.
[13] W. Waycott, B.S. Fort, E.J. Ryder and W.R. Michelmore. "Mapping
morphological gene relative to molecular marker in lettuce (Lactuca
sativa L.) ," Heredity 82: 245-251.1992.
[14] Association of Official Analytical Chemists (AOAC). Official Method
of Analysis Vol.2. 15th ed., The Association of Official Agricultural
Chemists, Virginia.,163 p. 1995
[15] D. Corroler, N. Desmasures and M. Gueguen. "Correlation between
polymerase chain reaction analysis of histidine biosyntheis operon,
randomly amplified polymorphic DNA analysis and phenotypic
characterization of dairy Lactococcus isolates," Appl Microbiol Biot,
vol. 51, 1999, pp. 91-99.
[16] J. Welsh, and M. McClelland. "Fingerprinting genome using PCR with
arbitary primers," Nucl Acids Res, vol. 18, 1990, pp. 7213-7218.
[17] M. Soller, and J.S. Beckman. "Genetic polymorphism in varietal
identification and genetic improvement," Theor Appl Genet, vol. 67,
1983, pp. 25-33.
[1] L. Leitao, P. Goulas, and J. Biolley, "Time-course of Rubisco oxidation
in baen (Phaseolus vulgaris L.)," Plant SCI, vol. 30, 2003, pp. 1-8..
[2] S.J. Oltmans, A.S. Lefohn, J.M. Harris, I. Galbally, H.E. Scheel, G.
Bodeker, E. Brunke, H. Claude, D. Tarasick, B.J. Johnson, P.
Simmonds, D. Shadwick, K. Anlaf, K. Hayden, F. Schmidlin, T.
Fujimoto, and H.E. Cuevas. "Long term changes in tropospheric ozone,"
Atmos Environ, vol. 40, 2006, pp. 3156-3173.
[3] E. Singh, S. Tiwari, and M. Agrawal,."Variability in antioxidant and
metabolite levels, growth and yield of two soybean varieties: An
assessment of anticipated yield losses under projected elevation of
ozone," Agr Ecosyst Environ, vol. 135, 2010, pp. 168-177.
[4] J.E. Miller, F.L. Booker, E.L. Ficus, A.S. Heagle, W.A. Pursley, S.F.
Vozzo, and W.W. Heck,. "Ultraviolet-B Radiation and Ozone Effects
on Growth, Yield, and Photosynthesis of Soybean," J Environ Qual,
vol. 23, 1994, pp. 83-91.
[5] A.S. Heagle. Ozone and Crop Yield. Annu Rev Phytopathol, vol. 27,
1989, pp. 397-423.
[6] http://www.pcd.or.th. Pollution Control Department of Thailand. 2004.
[7] H.B. Krishnan. "Biochemistry and molecular biology of soybean seed
storage proteins," J New Seeds, vol. 2, 2000, pp. 1-25.
[8] H. B. Krishnan. "Engineering soybean for enhanced sulfur amino acid
content," Crop Sci, vol. 45, 2005, pp. 454-461.
[9] N. C. Nielsen, R. Bassusner, and T. Beaman. The biochemistry and cell
biology of embryo storage proteins. In R. A. Larkins & I. K. Vasil
(Eds.), Cellular and molecular biology of plant seed development (pp.
151-220). Dordrecht: Kluwer Academic Publishers. 1997
[10] T. J. Brumm, and C. R. Jr. Hurburgh. "Quality of the 2002 soybean crop
from the United States," Louis, MO: American Soybean Association.
2002
[11] C. G. Zarkadas, Z.-R. Yu, H. D. Voldeng, and A. Minero-Amador.
"Assessment of the protein quality of a new high-protein soybean
cultivar by amino acid analysis," J Agr Food Chem, vol. 41, 1993, pp.
616-623.
[12] C. G. Zarkadas, H. D. Voldeng, Z.-R. Yu, and V. Choi. "Assessment of
the protein quality of nine northern adapted yellow and brown seed
coated soybean cultivars by amino acid analysis," J Agr Food Chem,
vo.l 47, 1999, pp. 5009-5018.
[13] W. Waycott, B.S. Fort, E.J. Ryder and W.R. Michelmore. "Mapping
morphological gene relative to molecular marker in lettuce (Lactuca
sativa L.) ," Heredity 82: 245-251.1992.
[14] Association of Official Analytical Chemists (AOAC). Official Method
of Analysis Vol.2. 15th ed., The Association of Official Agricultural
Chemists, Virginia.,163 p. 1995
[15] D. Corroler, N. Desmasures and M. Gueguen. "Correlation between
polymerase chain reaction analysis of histidine biosyntheis operon,
randomly amplified polymorphic DNA analysis and phenotypic
characterization of dairy Lactococcus isolates," Appl Microbiol Biot,
vol. 51, 1999, pp. 91-99.
[16] J. Welsh, and M. McClelland. "Fingerprinting genome using PCR with
arbitary primers," Nucl Acids Res, vol. 18, 1990, pp. 7213-7218.
[17] M. Soller, and J.S. Beckman. "Genetic polymorphism in varietal
identification and genetic improvement," Theor Appl Genet, vol. 67,
1983, pp. 25-33.
@article{"International Journal of Biological, Life and Agricultural Sciences:62227", author = "Orose Rugchati and Kanita Thanacharoenchanaphas", title = "Simulation of Increased Ambient Ozone to Estimate Nutrient Content and Genetic Change in Two Thai Soybean Cultivars", abstract = "This research studied the simulation of increased
ambient ozone to estimate nutrient content and genetic changes in
two Thai soybean cultivars (Chiang Mai 60 and Srisumrong 1).
Ozone stress conditions affected proteins and lipids. It was found
that proteins decreased, but lipids increased. Srisumrong 1 cultivars
were more sensitive to ozone stress than Chiang Mai 60 cultivars.
The effect of ozone stress conditions on plant phenotype and
genotype was analyzed using the AFLP technique for the 2 Thai
soybean cultivars (Chiang Mai 60 and Srisumrong 1).", keywords = "simulation, ambient ozone estimate, nutrient content,
genetic changes , Thai soybean", volume = "5", number = "11", pages = "815-3", }
