Classifying of Maize Inbred Lines into Heterotic Groups using Diallel Analysis
The selection of parents and breeding strategies for
the successful maize hybrid production will be facilitated by
heterotic groupings of parental lines and determination of combining
abilities of them. Fourteen maize inbred lines, used in maize breeding
programs in Iran, were crossed in a diallel mating design. The 91 F1
hybrids and the 14 parental lines were studied during two years at
four locations of Iran for investigation of combining ability of
gentypes for grain yield and to determine heterotic patterns among
germplasm sources, using both, the Griffing-s method and the biplot
approach for diallel analysis. The graphical representation offered by
biplot analysis allowed a rapid and effective overview of general
combining ability (GCA) and specific combining ability (SCA)
effects of the inbred lines, their performance in crosses, as well as
grouping patterns of similar genotypes. GCA and SCA effects were
significant for grain yield (GY). Based on significant positive GCA
effects, the lines derived from LSC could be used as parent in crosses
to increase GY. The maximum best- parent heterosis values and
highest SCA effects resulted from crosses B73 × MO17 and A679 ×
MO17 for GY. The best heterotic patterns were LSC × RYD, which
would be potentially useful in maize breeding programs to obtain
high-yielding hybrids in the same climate of Iran.
[1] R. W. Allard, Principles of plant breeding, 2nd edition, John Wiley and
Sons, Inc. USA, 1999.
[2] C. Barata, and M. Carena, "Classification of North Dakota maize inbred
lines into heterotic groups based on molecular and testcross data,"
Euphytica, vol. 151, pp. 339-349, 2006
[3] O. B. Bello, and G. Olaoye, "Combining ability for maize grain yield
and other agronomic characters in a typical southern guinea savanna
ecology of Nigeria," African Journal of Biotechnology, vol. 8, pp. 2518-
2522, 2009.
[4] S, Bhatnagar, F. J. Betran, and L. W. Rooney, "Combining ability of
quality protein maize inbreds," Crop Science, vol. 44, pp. 1997-2005,
2004.
[5] R. Choukan, "Evaluation of grain yield and yield components in maize
using diallel crosses," Iranian Journal of Crop Science, vol. 3, pp. 1-8,
2001.
[6] R. Choukan, "Heterotic grouping of maize inbred lines based on specific
combining ability with tester lines," Seed and Plant, vol. 22, pp. 399-
409, 2006.
[7] R. Choukan, A. Hossainzadeh, M. R. Ghannadha, M. L. Warburton, A.
R. Talei and S. A. Mohammadi, "Use of SSR data to determine
relationships and potential heterotic groupings within medium to late
maturing Iranian maize inbred lines," Field Crops Research, vol. 95, pp.
212-222, 2006.
[8] D. S. Falconer, Introduction to quantitative genetics, 3rd edition,
Longman grp., Essex, 1979.
[9] X. M. Fan, H. M. Chen, J. Tan, C. X. Xu, Y. D. Zhang, L. M. Luo, Y. X.
Huang and M. S. Kang, "Combining abilities for yield and yield
components in maize," Maydica, vol. 53, pp. 39-46, 2008.
[10] X. M. Fan, J. Tan, J. Y. Yang and H. M. Chen, "Combining ability and
heterotic grouping of ten temperate, subtropical and tropical quality
protein maize inbreds," Maydica, vol. 49, pp. 267-272, 2004.
[11] X. M. Fan, J. Tan, J. Y. Yang, F. Liu, B. H. Huang and Y. X. Huang,
"Study on combining ability for yield and genetic relationship between
exotic tropical, subtropical maize inbreeds and domestic temperate maize
inbreeds," Scientica Agriculture Sinica, vol. 35, pp. 743-749, 2002.
[12] W. R. Fehr, Principles of cultivar development, McGraw-Hill Inc., New
York, 1987.
[13] C. O. Gardner, and S. A. Eberhart, "Analysis and interpretation of the
variety cross diallel and related populations," Biometrics, vol. 22, pp.
439-452, 1966.
[14] S. Gonzalez, H. Cordova, S. Rodrigue, H. de Leon and V. M. Serrato,
"Determinacion de un patron heterotico a partir de la evaluacion de un
dialelo de diez lineas de maiz subtropical," Agron. Mesoamericana, vol.
8, pp. 1-7, 1997.
[15] B. Griffing, "Concept of general and specific combining ability in
relation to diallel crossing systems," Australian Journal of Biological
Science, vol. 9, pp. 463-493, 1956.
[16] G. C. Han, S. K. Vasal, D. L. Beck and E. Elis, "Combining ability of
inbred lines derived from CIMMYT maize (Zea mays L.) germplasm,"
Maydica, vol. 36, pp. 57-64, 1991.
[17] K. D. Kauffman, C. W. Crum and M. F. Lindsey, "Exotic germplasms in
a corn breeding program," Illinois Corn Breeding School, vol. 18, pp. 6-
39, 1982.
[18] M. D. Melani, and M. J. Carena, "Alternative maize heterotic pattern for
the Northern Corn Belt," Crop Science, vol. 45, pp. 2186-2194, 2005.
[19] K. H. Mostafavi, R. Choukan, M. Taeb, M. R. Bihamta and E. Majidi
Heravan, "Study of the gene action in controlling agronomic traits in
maize (Zea mays L.) using diallel crossing design," Iranian Journal of
Crop Science, vol. 10, pp. 331-348, 2009.
[20] J. C. Reif, A. E. Melchinger, X. C. Xia, M. L. Warburton, D. A.
Hoisington, S. K. Vasal, D. Beck, M. Bohn and M. Frisch, "Use of SSRs
for establishing heterotic groups in subtropical maize," Theoretical
Applied Genetics, vol. 107, pp. 947-957, 2003.
[21] J. S. C. Smith, and O. S Smith, "Fingerprinting crop varieties,"
Advances in Agronomy, vol. 47, pp. 85-129, 1992.
[22] J. R. Sughroue, and A. R. Hallauer, "Analysis of the diallel mating
design for maize inbred line," Crop Science, vol. 37, pp. 400-405, 1997.
[23] A. Terron, E. Preciado, H. Cordova, H. Mickelson and R. Lopez,
"Determinacion del patron heterotico de 30 lineas de maiz derivadas de
la poblacion 43SR del CIMMYT," Agron. Mesoamericana, vol. 8, pp.
26-34, 1997.
[24] W. Yan, "GGEbiplot - a Windows application for graphical analysis of
multi-environment trial data and other types of two way data,"
Agronomy Journal, vol. 93, pp. 1111-1118, 2001.
[25] W. Yan, and A. Hunt, "Biplot analysis of diallel data," Crop Science,
vol. 42, pp. 21-30, 2002.
[26] Y. Zhang, M. S. Kang and K. R. Lamkey, "DIALLEL- SAS05: A
Comprehensive Program for Griffing-s and Gardner- Eberhart
Analysis," Agronomy Journal, vol. 97, pp. 1097-1106, 2005.
[1] R. W. Allard, Principles of plant breeding, 2nd edition, John Wiley and
Sons, Inc. USA, 1999.
[2] C. Barata, and M. Carena, "Classification of North Dakota maize inbred
lines into heterotic groups based on molecular and testcross data,"
Euphytica, vol. 151, pp. 339-349, 2006
[3] O. B. Bello, and G. Olaoye, "Combining ability for maize grain yield
and other agronomic characters in a typical southern guinea savanna
ecology of Nigeria," African Journal of Biotechnology, vol. 8, pp. 2518-
2522, 2009.
[4] S, Bhatnagar, F. J. Betran, and L. W. Rooney, "Combining ability of
quality protein maize inbreds," Crop Science, vol. 44, pp. 1997-2005,
2004.
[5] R. Choukan, "Evaluation of grain yield and yield components in maize
using diallel crosses," Iranian Journal of Crop Science, vol. 3, pp. 1-8,
2001.
[6] R. Choukan, "Heterotic grouping of maize inbred lines based on specific
combining ability with tester lines," Seed and Plant, vol. 22, pp. 399-
409, 2006.
[7] R. Choukan, A. Hossainzadeh, M. R. Ghannadha, M. L. Warburton, A.
R. Talei and S. A. Mohammadi, "Use of SSR data to determine
relationships and potential heterotic groupings within medium to late
maturing Iranian maize inbred lines," Field Crops Research, vol. 95, pp.
212-222, 2006.
[8] D. S. Falconer, Introduction to quantitative genetics, 3rd edition,
Longman grp., Essex, 1979.
[9] X. M. Fan, H. M. Chen, J. Tan, C. X. Xu, Y. D. Zhang, L. M. Luo, Y. X.
Huang and M. S. Kang, "Combining abilities for yield and yield
components in maize," Maydica, vol. 53, pp. 39-46, 2008.
[10] X. M. Fan, J. Tan, J. Y. Yang and H. M. Chen, "Combining ability and
heterotic grouping of ten temperate, subtropical and tropical quality
protein maize inbreds," Maydica, vol. 49, pp. 267-272, 2004.
[11] X. M. Fan, J. Tan, J. Y. Yang, F. Liu, B. H. Huang and Y. X. Huang,
"Study on combining ability for yield and genetic relationship between
exotic tropical, subtropical maize inbreeds and domestic temperate maize
inbreeds," Scientica Agriculture Sinica, vol. 35, pp. 743-749, 2002.
[12] W. R. Fehr, Principles of cultivar development, McGraw-Hill Inc., New
York, 1987.
[13] C. O. Gardner, and S. A. Eberhart, "Analysis and interpretation of the
variety cross diallel and related populations," Biometrics, vol. 22, pp.
439-452, 1966.
[14] S. Gonzalez, H. Cordova, S. Rodrigue, H. de Leon and V. M. Serrato,
"Determinacion de un patron heterotico a partir de la evaluacion de un
dialelo de diez lineas de maiz subtropical," Agron. Mesoamericana, vol.
8, pp. 1-7, 1997.
[15] B. Griffing, "Concept of general and specific combining ability in
relation to diallel crossing systems," Australian Journal of Biological
Science, vol. 9, pp. 463-493, 1956.
[16] G. C. Han, S. K. Vasal, D. L. Beck and E. Elis, "Combining ability of
inbred lines derived from CIMMYT maize (Zea mays L.) germplasm,"
Maydica, vol. 36, pp. 57-64, 1991.
[17] K. D. Kauffman, C. W. Crum and M. F. Lindsey, "Exotic germplasms in
a corn breeding program," Illinois Corn Breeding School, vol. 18, pp. 6-
39, 1982.
[18] M. D. Melani, and M. J. Carena, "Alternative maize heterotic pattern for
the Northern Corn Belt," Crop Science, vol. 45, pp. 2186-2194, 2005.
[19] K. H. Mostafavi, R. Choukan, M. Taeb, M. R. Bihamta and E. Majidi
Heravan, "Study of the gene action in controlling agronomic traits in
maize (Zea mays L.) using diallel crossing design," Iranian Journal of
Crop Science, vol. 10, pp. 331-348, 2009.
[20] J. C. Reif, A. E. Melchinger, X. C. Xia, M. L. Warburton, D. A.
Hoisington, S. K. Vasal, D. Beck, M. Bohn and M. Frisch, "Use of SSRs
for establishing heterotic groups in subtropical maize," Theoretical
Applied Genetics, vol. 107, pp. 947-957, 2003.
[21] J. S. C. Smith, and O. S Smith, "Fingerprinting crop varieties,"
Advances in Agronomy, vol. 47, pp. 85-129, 1992.
[22] J. R. Sughroue, and A. R. Hallauer, "Analysis of the diallel mating
design for maize inbred line," Crop Science, vol. 37, pp. 400-405, 1997.
[23] A. Terron, E. Preciado, H. Cordova, H. Mickelson and R. Lopez,
"Determinacion del patron heterotico de 30 lineas de maiz derivadas de
la poblacion 43SR del CIMMYT," Agron. Mesoamericana, vol. 8, pp.
26-34, 1997.
[24] W. Yan, "GGEbiplot - a Windows application for graphical analysis of
multi-environment trial data and other types of two way data,"
Agronomy Journal, vol. 93, pp. 1111-1118, 2001.
[25] W. Yan, and A. Hunt, "Biplot analysis of diallel data," Crop Science,
vol. 42, pp. 21-30, 2002.
[26] Y. Zhang, M. S. Kang and K. R. Lamkey, "DIALLEL- SAS05: A
Comprehensive Program for Griffing-s and Gardner- Eberhart
Analysis," Agronomy Journal, vol. 97, pp. 1097-1106, 2005.
@article{"International Journal of Biological, Life and Agricultural Sciences:49922", author = "Mozhgan Ziaie Bidhendi and Rajab Choukan and Farokh Darvish and Khodadad Mostafavi and Eslam Majidi", title = "Classifying of Maize Inbred Lines into Heterotic Groups using Diallel Analysis", abstract = "The selection of parents and breeding strategies for
the successful maize hybrid production will be facilitated by
heterotic groupings of parental lines and determination of combining
abilities of them. Fourteen maize inbred lines, used in maize breeding
programs in Iran, were crossed in a diallel mating design. The 91 F1
hybrids and the 14 parental lines were studied during two years at
four locations of Iran for investigation of combining ability of
gentypes for grain yield and to determine heterotic patterns among
germplasm sources, using both, the Griffing-s method and the biplot
approach for diallel analysis. The graphical representation offered by
biplot analysis allowed a rapid and effective overview of general
combining ability (GCA) and specific combining ability (SCA)
effects of the inbred lines, their performance in crosses, as well as
grouping patterns of similar genotypes. GCA and SCA effects were
significant for grain yield (GY). Based on significant positive GCA
effects, the lines derived from LSC could be used as parent in crosses
to increase GY. The maximum best- parent heterosis values and
highest SCA effects resulted from crosses B73 × MO17 and A679 ×
MO17 for GY. The best heterotic patterns were LSC × RYD, which
would be potentially useful in maize breeding programs to obtain
high-yielding hybrids in the same climate of Iran.", keywords = "biplot, diallel, Griffing, Heterotic pattern", volume = "6", number = "7", pages = "404-4", }
