DEVELOPMENT OF MAIZE GENOTYPES (Zea mays L.) BY USING IN VIVO DOUBLED HAPLOID TECHNIQUE
Year 2023,
Volume: 28 Issue: 1, 1 - 6, 21.06.2023
Sinem Zere Taşkın
,
Ugur Bilgili
Abstract
Doubled haploid technology has become an increasingly popular and important tool for developing new maize lines (Zea mays L.) breeding. Conventional maize breeding requires repeated self-pollination for about six to ten generations to obtain homozygous inbred lines. Completely homozygous lines can be produced in only two generations by using doubled haploid technology. In vivo induction of the maternal haploid method was used for the production of doubled haploid lines. 32 different donors pollinated with haploid inducer line Stock6. Haploid seeds were identified visually by using dominant anthocyanin color marker genes R1-nj. Haploid induction rates (HIR) and chromosome doubling rate (CDR) were determined. 488 putative haploid seeds were obtained. The average haploid induction rate was calculated as 2.0%, the average chromosome doubling rate was 52,3%. Results of this study 20 doubled haploid lines were developed.
Supporting Institution
Bursa Uludag University BAP council
Project Number
FDK-2021-491
Thanks
This research was supported by the Unit of Scientific Research Projects, Bursa Uludag University (Project Number: FDK-2021-491; Project Leader: Prof. Dr. Ugur Bilgili). The authors want to thank the BAP council for their support.
References
- Auger, D.L., T.S. Ream and J.A. Bırchler. 2004. A test for a
metastable epigenetic component of heterosis using haploid
induction in maize. Theor. Appl. Genet. 108: 1017-1023.
- Cengiz, R. and K.Z. Korkut. 2020. Development of doubled
haploid maize lines by using in vivo haploid technique.
Biotech Studies 29(1): 1-7
- Cerit, I., G. Comertpay, R. Oyucu, B. Cakır, R. Hatipoglu and H.
Ozkan. 2016. Determination of haploid induction rates of
different inducer lines used for in-vivo doubled haploid
technique in hybrid maize breeding. Journal of Field Crops
Central Research Institute. 25 (Special issue-1): 52-57 (in
Turkish).
- Chaikam, V., W. Molenaar, A.E. Melchinger and P.M.
Boddupalli. 2019. Doubled haploid technology for line
development in maize: technical advances and prospects.
Theor. Appl. Genet. 132: 3227–3243.
- Chang, M.T. and E.H. Coe. 2009. Doubled haploids. In:
Molecular Genetic Approaches to Maize Improvement, ed.
Kriz, A.L. and Larkins, B.A., 127–142, Springer Berlin
Heidelberg, Berlin, Heidelberg.
- Chase, S.S. 1949. Monoploid frequencies in commercial double
cross hybrid maize, and in its component single cross hybrids
and inbred lines. Genetics 34: 328–332.
- Coe, E.H. 1959. A line of maize with high haploid frequency.
American Naturalist 93: 381–382.
- Coe, E.H. and K.R. Sarkar. 1964. The detection of haploids in
maize. Journal of Heredity. 55: 231-233.
- Deimling S., F. Rober and H.H. Geiger. 1997. Methodik und
genetik der in vivo haploiden induktion bei mais. Votr
Pflanzenzüchtg 38: 203-224.
- De La Fuente, G.N., U.K. Frei, B. Trampe, D. Nettleton, W.
Zhang and T. Lubberstedt. 2018. A Diallel analysis of a maize
donor population response to in vivo maternal haploid
induction I: Inducibility. Crop Sci. 58: 1830–1837.
- Dong, X., X. Xu, J. Miao, L. Li, D. Zhang, X. Mi, C. Liu, X. Tian,
A.E. Melchinger and S. Chen. 2013. Fine mapping of qhir1
influencing in vivo haploid induction in maize. Theor. Appl.
Genet. 126: 1713–1720.
- Eder, J. and S.T. Chalyk. 2002. In vivo haploid induction in maize.
Theor. Appl. Genet. 104: 703-708.
- Gayen, P., J.K. Madan, R. Kumar and K.R. Sarkar.1994.
Chromosome doubling in haploids through colchisine. Maize
Genet. Coop. Newsletter 68: 65.
- Geiger, H.H. 2009. Doubled haploids. In: Maize handbook -
volume II: genetics and genomics, eds. Bennetzen, J.L. and
Hake, S., 641-657, Springer Science and Business Media,
New York.
- Geiger, H.H. and G.A. Gordillo. 2010. Doubled haploids in hybrıd
maize breeding. University of Hohenheim, Institute of Plant Breeding, Seed Science, and Population Genetics, 70593
- Stuttgart, Germany. Maydica 54: 485-499.
Kalinowska, K., S. Chamas, K. Unkel, D. Demidov, I.
Lermontova, T. Dresselhaus, J. Kumlehn, F. Dunemann and
A. Houben. 2019. State-of-the-art and novel developments of
in vivo haploid technologies. Theor. Appl. Genet. 132: 593–
605.
- Kusaksiz, T. and E.K. Kusaksiz. 2018. The performances of some
new dent maize (Zea mays L.) cultivars grown as main crop
in a Mediterranean environment. Turk. J. Field Crops. 23(2):
187-194.
- Lashermes, P. and M. Beckert. 1988. Genetic control of maternal
haploidy in maize (Zea Mays L.) and selection of haploid
inducing lines. Theor. Appl. Genet. 76: 405–410.
- Mansfield, B.D. and R.H. Mumm. 2014. Survey of plant density
tolerance in U.S. maize germplasm. Crop Sci. 54: 157-173.
- Melchinger, AE., PC. Brauner, J. Bohm and W. Schipprack. 2016.
In vivo haploid induction in maize: comparison of different
testing regimes for measuring haploid induction rates. Crop
Sci. 56: 1127–1135.
- Meng, D., H. Luo, Z. Dong, W. Huang, F. Liu, F. Li, S. Chen, H.
Yu and W. Jin. 2022. Overexpression of Modified CENH3 in
Maize Stock6-Derived Inducer Lines Can Effectively
Improve Maternal Haploid Induction Rates. Front. Plant Sci.
13:892055.
- Ren, J., P. Wu, B. Trampe, X. Tian, T. Lubberstedt and S. Chen.
2017. Novel technologies in doubled haploid line
development. Plant Biotechnol. J. 15: 1361–1370.
- Rotarenco, V.A. 2002. Production of matroclinous maize haploids
following natural and artificial pollination with a haploid
inducer. Maize Genet. Coop. News Lett. 76: 16.
- Rotarenco, V.A., G. Dicu, D. State and S. Fuia. 2010. New
inducers of maternal haploids in maize. Maize Genet. Coop.
News Lett. 84: 15.
- Röber, F.K., G.A. Gordillo and H.H. Geiger. 2005. In vivo haploid
induction in maize performance of new inducers and
significance of doubled haploid lines in hybrid breeding.
Maydica 50: 275–283.
- Wang, B., L. Zhu, B. Zhao, Y. Zhao, Y. Xie, Z. Zheng, Y. Li, J.
Sun and H. Wang. 2019. Development of a haploid-inducer
mediated genome editing system for accelerating maize
breeding. Mol. Plant. 12(4): 597–602.
- Uliana Trentin, H., G. Batiru, U.K. Frei, S. Duttaand and T.
Lubberstedt. 2022. Investigating the effect of the interaction
of maize inducer and donor backgrounds on haploid induction
rates. Plants 11: 1527.
- Zararsız, D., S. Yanıkoglu, L. Ozturk, I. Turgut, S. Kizik and B.
Bilgin. 2019. Production of double haploid plants using in
vivo haploid techniques in maize. Journal of Agricultural
Sciences 25(1): 62-69.
Year 2023,
Volume: 28 Issue: 1, 1 - 6, 21.06.2023
Sinem Zere Taşkın
,
Ugur Bilgili
Project Number
FDK-2021-491
References
- Auger, D.L., T.S. Ream and J.A. Bırchler. 2004. A test for a
metastable epigenetic component of heterosis using haploid
induction in maize. Theor. Appl. Genet. 108: 1017-1023.
- Cengiz, R. and K.Z. Korkut. 2020. Development of doubled
haploid maize lines by using in vivo haploid technique.
Biotech Studies 29(1): 1-7
- Cerit, I., G. Comertpay, R. Oyucu, B. Cakır, R. Hatipoglu and H.
Ozkan. 2016. Determination of haploid induction rates of
different inducer lines used for in-vivo doubled haploid
technique in hybrid maize breeding. Journal of Field Crops
Central Research Institute. 25 (Special issue-1): 52-57 (in
Turkish).
- Chaikam, V., W. Molenaar, A.E. Melchinger and P.M.
Boddupalli. 2019. Doubled haploid technology for line
development in maize: technical advances and prospects.
Theor. Appl. Genet. 132: 3227–3243.
- Chang, M.T. and E.H. Coe. 2009. Doubled haploids. In:
Molecular Genetic Approaches to Maize Improvement, ed.
Kriz, A.L. and Larkins, B.A., 127–142, Springer Berlin
Heidelberg, Berlin, Heidelberg.
- Chase, S.S. 1949. Monoploid frequencies in commercial double
cross hybrid maize, and in its component single cross hybrids
and inbred lines. Genetics 34: 328–332.
- Coe, E.H. 1959. A line of maize with high haploid frequency.
American Naturalist 93: 381–382.
- Coe, E.H. and K.R. Sarkar. 1964. The detection of haploids in
maize. Journal of Heredity. 55: 231-233.
- Deimling S., F. Rober and H.H. Geiger. 1997. Methodik und
genetik der in vivo haploiden induktion bei mais. Votr
Pflanzenzüchtg 38: 203-224.
- De La Fuente, G.N., U.K. Frei, B. Trampe, D. Nettleton, W.
Zhang and T. Lubberstedt. 2018. A Diallel analysis of a maize
donor population response to in vivo maternal haploid
induction I: Inducibility. Crop Sci. 58: 1830–1837.
- Dong, X., X. Xu, J. Miao, L. Li, D. Zhang, X. Mi, C. Liu, X. Tian,
A.E. Melchinger and S. Chen. 2013. Fine mapping of qhir1
influencing in vivo haploid induction in maize. Theor. Appl.
Genet. 126: 1713–1720.
- Eder, J. and S.T. Chalyk. 2002. In vivo haploid induction in maize.
Theor. Appl. Genet. 104: 703-708.
- Gayen, P., J.K. Madan, R. Kumar and K.R. Sarkar.1994.
Chromosome doubling in haploids through colchisine. Maize
Genet. Coop. Newsletter 68: 65.
- Geiger, H.H. 2009. Doubled haploids. In: Maize handbook -
volume II: genetics and genomics, eds. Bennetzen, J.L. and
Hake, S., 641-657, Springer Science and Business Media,
New York.
- Geiger, H.H. and G.A. Gordillo. 2010. Doubled haploids in hybrıd
maize breeding. University of Hohenheim, Institute of Plant Breeding, Seed Science, and Population Genetics, 70593
- Stuttgart, Germany. Maydica 54: 485-499.
Kalinowska, K., S. Chamas, K. Unkel, D. Demidov, I.
Lermontova, T. Dresselhaus, J. Kumlehn, F. Dunemann and
A. Houben. 2019. State-of-the-art and novel developments of
in vivo haploid technologies. Theor. Appl. Genet. 132: 593–
605.
- Kusaksiz, T. and E.K. Kusaksiz. 2018. The performances of some
new dent maize (Zea mays L.) cultivars grown as main crop
in a Mediterranean environment. Turk. J. Field Crops. 23(2):
187-194.
- Lashermes, P. and M. Beckert. 1988. Genetic control of maternal
haploidy in maize (Zea Mays L.) and selection of haploid
inducing lines. Theor. Appl. Genet. 76: 405–410.
- Mansfield, B.D. and R.H. Mumm. 2014. Survey of plant density
tolerance in U.S. maize germplasm. Crop Sci. 54: 157-173.
- Melchinger, AE., PC. Brauner, J. Bohm and W. Schipprack. 2016.
In vivo haploid induction in maize: comparison of different
testing regimes for measuring haploid induction rates. Crop
Sci. 56: 1127–1135.
- Meng, D., H. Luo, Z. Dong, W. Huang, F. Liu, F. Li, S. Chen, H.
Yu and W. Jin. 2022. Overexpression of Modified CENH3 in
Maize Stock6-Derived Inducer Lines Can Effectively
Improve Maternal Haploid Induction Rates. Front. Plant Sci.
13:892055.
- Ren, J., P. Wu, B. Trampe, X. Tian, T. Lubberstedt and S. Chen.
2017. Novel technologies in doubled haploid line
development. Plant Biotechnol. J. 15: 1361–1370.
- Rotarenco, V.A. 2002. Production of matroclinous maize haploids
following natural and artificial pollination with a haploid
inducer. Maize Genet. Coop. News Lett. 76: 16.
- Rotarenco, V.A., G. Dicu, D. State and S. Fuia. 2010. New
inducers of maternal haploids in maize. Maize Genet. Coop.
News Lett. 84: 15.
- Röber, F.K., G.A. Gordillo and H.H. Geiger. 2005. In vivo haploid
induction in maize performance of new inducers and
significance of doubled haploid lines in hybrid breeding.
Maydica 50: 275–283.
- Wang, B., L. Zhu, B. Zhao, Y. Zhao, Y. Xie, Z. Zheng, Y. Li, J.
Sun and H. Wang. 2019. Development of a haploid-inducer
mediated genome editing system for accelerating maize
breeding. Mol. Plant. 12(4): 597–602.
- Uliana Trentin, H., G. Batiru, U.K. Frei, S. Duttaand and T.
Lubberstedt. 2022. Investigating the effect of the interaction
of maize inducer and donor backgrounds on haploid induction
rates. Plants 11: 1527.
- Zararsız, D., S. Yanıkoglu, L. Ozturk, I. Turgut, S. Kizik and B.
Bilgin. 2019. Production of double haploid plants using in
vivo haploid techniques in maize. Journal of Agricultural
Sciences 25(1): 62-69.