LINE×TESTER ANALYSIS OF THE SECOND GENERATION OF MAIZE GENOTYPES IN SULAIMANI AGROCLIMATIC CONDITIONS, IRAQ

Authors

  • Lanja M. A.

DOI:

https://doi.org/10.36103/fkrz2h48

Keywords:

general and specific combining ability, heterosis, dominance average degree, climate change, climate action

Abstract

Eight inbred lines of maize (Zea mays L.) and their 16 F2 hybrids were used in this investigation during the spring season 2023, utilizing the line × tester mating design. This study was conducted at two environmentally different locations at Sulaimani: Dukan and Qlyasan. The hybridization consisted of four inbred lines (NADH905, NADH102, NA106, and SaraNA) which were used as lines with four inbred lines (NA225, NAHD503, ZN12, and NAPI 5012) which were used as testers. The cross SaraNA×NAPI5012 and NADH 905×NA225 recorded the highest values for kernel yield at Dukan and Qlyasan locations respectively. The maximum heterosis values concerning kernel yield were obtained by the crosses SaraNA×NAPI5012 and NA106×NAPI5012 at Dukan and Qlyasan respectively. The maximum positive GCA effects for kernel yield were recorded by parents SaraNA and ZN12 at Dukan and parents NA106 and NA225 at Qlyasan locations. SCA effect for the crosses concerning kernel yield showed that the crosses SaraNA×NAPI5012 and NADH 905×ZN12 obtained the maximum positive SCA values at Dukan and Qlyasan locations respectively.   

References

Abd El-Aty, M. S., A. E.-W. Abd El-Hameed, E. A. E.-F. El-Sayed, and M. S. R. Amer 2018. Evaluation and classification of sixteen new yellow maize inbred lines using line × tester analysis in different locations under Egyptian environment. Fresenius Environmental Bulletin, 27(7): 4986-4994.

Abdulhamed, Z. A., S. E. Faiath, H. A. Ajaj, and Y. A. Mohammed 2021. Genetic parameters estimate through line × tester analysis for the stay green, yield and quality in maize (Zea mays L.). Annals of the Rom. Soc. for Cell Bio., 25(4): 8597-8611.

Abdulhamed, Z., S. Abas, and A. Abed 2020. Studying some genetic in maize by line× tester analysis. Int. J. of Agri. and Stat. Sci., 16(1):1421-1426.

Abdulkhaleq, D.A. 2011. Analysis of Full Diallel Cross in Maize (Zea mays L.). Ph.D. Dissertation, Faculty of Agricultural Sciences, University of Sulaimani, Iraq.

Al-Faraji, F. 2020. Estimation of Gene Action, Genetic Diversity and Hybrid Vigor in Lines of Maize (Zea mays L.) Using the SSR Technology. Ph.D. Dissertation, The Agriculture College of Anbar University, Iraq.

Ali, F., Ahsan, M., Saeed, N. A., Ahmed, M., Qurban, A., N. Kanwal, M. M. Tehseen, U. Ijaz, I. Bibi, and N. K. Niazi 2014. Establishment and optimization of callus-to-plant regeneration system using mature and immature embryos of maize (Zea mays L.). Int. J. of Agri. and Bio., 16(1):111-117.

Ambikabathy, A., N.J. Selvam, and D. T. Selvi 2019. Determination of combining ability and heterosis for yield and yield related traits in maize hybrids based on line × tester. Res. J. of Agri. Sci., 10(1): 215-220.

Amiruzzaman, M. 2010. Exploitation of Hybrid Vigor from Normal and Quality Protein Maize Crosses. Dept. Genetics and Plant Breeding, Bangladesh Agricultural University, Mymensingh.

Annonymous 2004. Annual report 1989, Beyond subsistence. New Options for Asian Farmers, CIMMYT, Mexico. pp. 145-148.

Araus, J. L., C. Sánchez, and L. Cabrera‐Bosquet 2010. Is heterosis in maize mediated through better water use. New Phytologist, 187(2): 392-406.

Arsode, P., K. Murali Krishna, N. Sunil, V. Sree, and A. Ravi Charan 2017. Combining ability and heterosis studies for grain yield and its components in hybrids of quality protein maize (Zea mays L.). Int. J. of Curr. Micro. and App. Scie., 6(12), 2538-2545.

Assefa, T., H. Zeleke, T. Afriye and P. Otyama 2017. Line × tester analysis of tropical high land maize (Zea mays L.) inbred lines top crossed with three east African maize populations. A. J. of P. Sci., 8(2): 126-136.

Alkazaali H.A., M.M.Elsahookie, and F. Y. Baktash. 2016. Flowering syndrome - Hybrid performance relationship in maize: 1- Field traits and growth rates, Iraqi Journal of Agricultural Sciences, 47(4): 900 - 909.

https://doi.org/10.36103/ijas.v47i4.518

Alkazaali H.A., and F. Y. Baktash. 2016. Impact of corn grain moisture at harvesting to agronomic traits in subsequent generation, Iraqi Journal of Agricultural Sciences 48: (Special Issue): 11-23.

https://doi.org/10.36103/ijas.v48iSpecial.240

Al-Kazaali, H.A., Baktash, F.Y. 2017. Impact of corn grain moisture at harvesting to agronomic traits in subsequent generation. Iraqi Journal of Agricultural Sciences, 48 (Specialissue): 18-23.

Baktash, F. Y., and H.A. Alkazaali. 2016. Effect of grain moisture of corn at harvesting on some agronomic traits. Iraqi Journal of Agricultural Sciences, 47(5): 1334 - 1339.

https://doi.org/10.36103/ijas.v47i5.514

Baktash, F. Y., and H.A. Alkazaali. 2016. Grain yield adn yield components of corn as influenced by harvesting moisture. Iraqi Journal of Agricultural Sciences, 47(5): 1340 - 1345.

https://doi.org/10.36103/ijas.v47i5.514

Baktash, F. Y., 2016. Modified mass selection within corn synthetic variety. Iraqi Journal of Agricultural Sciences, 47(1): 391 - 395.

https://doi.org/10.36103/ijas.v47i1.643

Begum, S., S. Alam, S. Omy, M. Amiruzzaman, and M. Rohman 2018. Inheritance and combing ability in maize using a 7×7 diallel cross. J. of P. Breed. and Crop Sci., 10(9):293-248.

Fan, X., Y. Zhang, W. Yao, H. Chen, J. Tan, C. Xu, X. Han, L. Luo, and M. Kang 2009. Classifying maize inbred lines into heterotic groups using a factorial mating design. Agron. J., 101(1): 106-112.

Joshi, V., R. Dubey and S. Marker 2002. Combining ability for polygenic traits in early maturing hybrids of maize (Zea mays L.). Ind. J. of Gen. and P. Breed., 62(04), 312-315.

Kachapur, R. M., M.C. Wali, S.C. Talekar, and S. I. Harlapur 2018. Combining ability and heterosis in early maturity maize (Zea mays L.). Maize J., 7(1): 27-32.

Kempthorne, O. 1957. An Introduction to Statistical Genetics. John Willey and Sons, Inc., New York, 545.

Manivannan, N. A. and J. Ganesan 2001. Line × tester analysis in sesame (Sesamum indicum L.). Ind. J. Agric. Res., 35: 90-94.

Morris, M. L., J. Risopoulos, and D. Beck 1999. Genetic Change in Farmer-Recycled Maize Seed: A Review of the Evidence. CIMMYT Economics Working Paper No. 99-07. Mexico, D.F.: CIMMYT.

Muhammd, S. M., N.T. Hammad, K. Rehmat, J. Muhammad, and S. Kashif. 2002. Interrelationships and path analysis of yield attributes in chick pea (Cicer arietinum L.). Int. J. for Agric. and Bio., 4(3): 404-406.

Muhammed, L. F. 2023. Genetic Analysis and Stability in Yield, its Components and Oil Quality of Maize Using Two Mating Desings. Ph.D. Dissertation, College of Agricultural Engineering Sciences, University of Sulaimani.

Prasanna, B. 2012. Diversity in global maize germplasm: characterization and utilization. J. of Bio., 37(5), 843-855.

Shah, S. T. H., M. S. I. Zamir, M.M. Waseem, A. Ali, M. Tahir, and W.B. Khalid 2009. Growth and yield response of maize (Zea mays L.) to organic and inorganic sources of nitrogen. Pak. J. Life Soc. Sci., 7(2),108-111.

Sharma, S., M. Narwal, R. Kumar, and S. Dass 2004. Line×tester analysis in maize (Zea mays L.). Forage Res., 30, 28-30.

Singh R.K., and B.D. Chaudhary 1985. Biometrical Methods in Quantitative Genetic Analysis; Kalyani Publishers; New Delhi: pp. 215–218.

Tesfaye, D., D. Abakemal, and E. Habte 2019. Combining ability of highland adapted double haploid maize inbred lines using line × tester mating design. East Afr. J. of Sci., 13(2), 121-134.

Tritarigh, S., Raheamezanpour, S. Choukan, R., Soltanloo, H. Mohammadi, Z., and M. Shiri 2020. Combining ability of maize (Zea mays L.) lines extracted from tropical / subtropical source and temperate testers. Acad. J. of Agric. Res., 8(2), 041-049.

Yadav, N. K., S. Sinha, J. Tiwari, and D. K. Thakur 2020. Line × tester model for evaluating the combining ability of some new white maize inbred lines. Int. J. of Curr. Micro. and App. Sci., Special Issue-10, 483-499.

Yadesa, L. M., S. Alamerew, and B. Tadesse 2021. Combining ability study for grain yield and agronomic traits of quality protein maize (Zea mays L.) inbred lines adapted to mid-altitude agro ecology of Ethiopia. Agro Bali: Agricultural Journal, 4(3), pp. 286-304. https://doi.org/10.37637/ab.v4i3.733

Yan, W., L. A. Hunt, Q. Sheng, and Z. Szlavnics 2000. Cultivar evaluation and mega‐environment investigation based on the gge bi-plot. Crop Sci., 40(3), pp. 597-605.

Zhiyan A. T. and M. A. Hussain. 2023. Combining ability and genetic parameters for yield and its components using line x tester analysis in summer squash. Iraqi Journal of Agricultural Sciences, 54(6):1784-1793. https://doi.org/10.36103/ijas.v54i6.1877

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Published

2024-08-26

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How to Cite

Lanja M. A. (2024). LINE×TESTER ANALYSIS OF THE SECOND GENERATION OF MAIZE GENOTYPES IN SULAIMANI AGROCLIMATIC CONDITIONS, IRAQ . IRAQI JOURNAL OF AGRICULTURAL SCIENCES, 55(4), 1419-1433. https://doi.org/10.36103/fkrz2h48

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